Optimum design of a composite floor system considering environmental and economic impacts

Arpini, Paulo Augusto T.; Loureiro, Mayane C.; Breda, Breno D.; Calenzani, Adenílcia F.; Alves, Élcio C.

doi:10.1590/S1983-41952022000300002

Abstracts

Abstract

The composite floor system, composed of steel deck and concrete slab, generates more efficient and economical structures. On the other hand, the design of this type of structure has a high complexity level due to the consideration of several variables. In this respect, the objective of this paper is to present the formulation of the optimization problem for a composite floor system (steel and concrete) considering such environmental as economic impacts. To formulate the optimization problem, the reduction of environmental impact was adopted as an objective function - assuming the CO₂ emission and the finance cost as parameters. The restrictions were taken by the limiting states imposed in standard NBR 8800:2008. The computer program was developed via Matlab R2016a and the optimization process was carried out using the Genetic Algorithm toolbox existing in this platform. Two application examples of the formulation at hand are presented: the first from the literature and the second from an existing building - in both situations the influences of different concrete compressive characteristic strengths were analyzed. The results of the optimization problem show a reduction in geometry and, consequently, in its weight. The solution found by the program reduces by up to 17.70% of CO₂ emissions and 17.47% of the finance cost. When was applying different concrete compressive strengths, the optimal solution for environmental impact did not get the lowest cost. In general, the steel deck formwork obtained the highest percentage of environmental impact, while the beams and girders, with the same shape configuration, had the highest finance cost. Therefore, it is shown that the optimal design solution to CO₂ emissions is not always the better solution for the finance cost.

Keywords:
steel-concrete composite floor system; cost and environmental impact; genetic algorithm

Resumo

O sistema de piso misto, composto por steel deck e laje de concreto, gera estruturas mais eficientes e econômicas. Por outro lado, o dimensionamento deste tipo de estrutura apresenta um elevado nível de complexidade devido à consideração de várias variáveis. Nesse sentido, o objetivo deste trabalho é apresentar a formulação de um problema de otimização para um sistema de piso misto (aço e concreto) considerando os impactos ambientais e econômicos. Para formular o problema, a redução do impacto ambiental foi adotada como função objetivo - assumindo como parâmetros da otimização a emissão de CO₂ e o custo financeiro. As restrições foram atendidas pelos estados limitadores impostos na norma NBR 8800:2008. A rotina foi desenvolvida via Matlab R2016a e o processo de otimização foi realizado utilizando o Algoritmo Genético existente na plataforma. São apresentados dois exemplos de aplicação da formulação em questão: o primeiro da literatura e o segundo de um edifício existente - em ambas as situações foram analisadas as influências de diferentes resistências características à compressão do concreto. Os resultados do problema de otimização mostram uma redução na geometria e, consequentemente, no seu peso. A solução encontrada pelo programa reduz em até 17.70% as emissões de CO₂ e até 17.47% o custo financeiro. Quando se aplicou diferentes resistências à compressão do concreto, a solução ótima de impacto ambiental não obteve o menor custo. Em geral, a fôrma de steel deck obteve o maior percentual de impacto ambiental, enquanto as vigas secundárias e principais, com a mesma configuração de forma, tiveram o maior custo financeiro. Portanto, mostra-se que a solução de projeto ideal para as emissões de CO₂ nem sempre é a melhor solução para o custo financeiro.

Palavras-chave:
sistema de piso misto de aço-concreto; custo e impacto ambiental; algoritmo genético

1. INTRODUCTION

During the conception of a structural system, several different variables must be considered (dimension of structural elements, materials, cost, constructive process, among others), to define the most adequate design solution from technical, cost, and environmental perspectives. The latter is of great importance for the current worldwide scenario, and it is considered a strategic advantage, paramount for the sustainable development of civil construction.

On the quest for perfecting engineering processes, design optimization is a tool capable of offering good results for the solution of problems concerning the analysis and design of structures. As such, metaheuristic methods are studied, inspired in nature and its biological processes.

Optimization problems in civil construction usually involve finding the most financially viable solution. Recently, Öztürk et al. [¹1 H. T. Öztürk, T. Dede, and E. Türker, "Optimum design of reinforced concrete counterfort retaining walls using TLBO, Jaya algorithm," Structures, vol. 25, pp. 285–296, 2020, http://dx.doi.org/10.1016/j.istruc.2020.03.020.
http://dx.doi.org/10.1016/j.istruc.2020.... ] used the TLBO and Jaya algorithms, while Kalemci et al. [²2 E. N. Kalemci, S. B. İkizler, T. Dede, and Z. Angın, "Design of reinforced concrete cantilever retaining wall using Grey wolf optimization algorithm," Structures, vol. 23, pp. 245–253, 2020, http://dx.doi.org/10.1016/j.istruc.2019.09.013.
http://dx.doi.org/10.1016/j.istruc.2019.... ] used the Gray Wolf Optimization algorithm (GWO) to optimize the ideal design of a reinforced concrete retaining wall, to minimize the cost and weight of the structure, respectively.

Genetic Algorithms (GA) were proposed by John Holland in the 1960s. Those are models inspired by the principles of natural selection proposed by Charles Darwin. Considered one of the most consolidated metaheuristic methods, the application of GA’s is observed in numerous areas, since this method presents high efficiency for finding globally optimized solutions [³3 H. R. Maier, S. Razavi, Z. Kapelan, L. S. Matott, J. Kasprzyk, and B. A. Tolson, "Introductory overview: Optimization using evolutionary algorithms and other metaheuristics," Environ. Model. Softw., vol. 114, pp. 195–213, 2019, http://dx.doi.org/10.1016/j.envsoft.2018.11.018.
http://dx.doi.org/10.1016/j.envsoft.2018... ].

Examples of GA applied to structural engineering include the optimization of reinforced concrete beams [⁴4 M. Shahnewaz, A. Rteil, and M. S. Alam, "Shear strength of reinforced concrete deep beams: a review with improved model by genetic algorithm and reliability analysis," Structures, vol. 23, pp. 494–508, 2020, http://dx.doi.org/10.1016/j.istruc.2019.09.006.
http://dx.doi.org/10.1016/j.istruc.2019.... ], [⁵5 E. Zhu et al., "Optimizing reinforced concrete beams under different load cases and material mechanical properties using genetic algorithms," Steel Compos. Struct., vol. 34, pp. 467–485, 2020. https://doi.org/http://dx.doi.org/10.12989/scs.2020.34.4.467.
https://doi.org/http://dx.doi.org/10.129... ], steel-concrete composite girders [⁶6 A. F. Tormen, Z. M. C. Pravia, F. B. Ramires, and M. Kripka, "Optimization of steel-concrete composite beams considering cost and environmental impact," Steel Compos. Struct., vol. 34, pp. 409–421, 2020. https://doi.org/http://dx.doi.org/10.12989/scs.2020.34.3.409.
https://doi.org/http://dx.doi.org/10.129... ], spatial steel frames [⁷7 M.-B. Prendes-Gero, A. Bello-García, J.-J. del Coz-Díaz, F.-J. Suárez-Domínguez, and P.-J. García Nieto, "Optimization of steel structures with one genetic algorithm according to three international building codes," Rev. Constr., vol. 17, pp. 47–59, 2018, http://dx.doi.org/10.7764/RDLC.17.1.47.
http://dx.doi.org/10.7764/RDLC.17.1.47... ], railway viaducts [⁸8 J. Malveiro, D. Ribeiro, C. Sousa, and R. Calçada, "Model updating of a dynamic model of a composite steel-concrete railway viaduct based on experimental tests," Eng. Struct., vol. 164, pp. 40–52, 2018, http://dx.doi.org/10.1016/j.engstruct.2018.02.057.
http://dx.doi.org/10.1016/j.engstruct.20... ] and bridges [⁹9 M. H. Ha, Q. A. Vu, and V. H. Truong, "Optimum design of stay cables of steel cable-stayed bridges using nonlinear inelastic analysis and genetic algorithm," Structures, vol. 16, pp. 288–302, 2018, http://dx.doi.org/10.1016/j.istruc.2018.10.007.
http://dx.doi.org/10.1016/j.istruc.2018.... ], [¹⁰10 M. Z. Abd Elrehim, M. A. Eid, and M. G. Sayed, "Structural optimization of concrete arch bridges using Genetic Algorithms," Ain Shams Eng J, vol. 10, no. 3, pp. 507–516, 2019, http://dx.doi.org/10.1016/j.asej.2019.01.005.
http://dx.doi.org/10.1016/j.asej.2019.01... ].

It is worth noting that the optimized solution is not always the best alternative when problem variables are subjected to a specific type of constraint. Kripakaran et al. [¹¹11 P. Kripakaran, B. Hall, and A. Gupta, "A genetic algorithm for design of moment-resisting steel frames," Struct. Multidiscipl. Optim., vol. 44, no. 4, pp. 559–574, 2011, http://dx.doi.org/10.1007/s00158-011-0654-7.
http://dx.doi.org/10.1007/s00158-011-065... ] developed a decision-making support system based on GA for the structural optimization of rigid steel frames and used the Modelling to Generate Alternatives (MGA) technique to determine structural solutions as close as possible to the optimized alternative. The ideal solution was chosen from a set of options that presented the best results.

From financial and environmental standpoints, the use of steel-concrete composite structures gained notoriety in civil construction for presenting performance improvements because of combining the use of both materials.

The presence of different materials increases the number of variables involved in the design of composite structures, making a more complex calculations and time-consuming if the conventionally used trial and error approach is adopted [¹²12 J. F. Santoro and M. Kripka, "Minimizing environmental impact from optimized sizing of reinforced concrete elements," Comput. Concr., vol. 25, pp. 111–118, 2020.]. However, manufacturers usually provide design tables for specific structural elements such as steel decks, which are ideal tools for implementing optimization techniques featuring discrete variables.

Numerous studies using different methods for the design optimization of steel-concrete composite structures are observed in scientific literature, such as Žula et al. [¹³13 T. Žula, S. Kravanja, and U. Klansek, "MINLP optimization of a composite I beam floor system," Steel Compos. Struct., vol. 22, no. 5, pp. 1163–1192, 2016, http://dx.doi.org/10.12989/scs.2016.22.5.1163.
http://dx.doi.org/10.12989/scs.2016.22.5... ], Matos et al. [¹⁴14 J. C. Matos, I. B. Valente, P. J. S. Cruz, and V. N. Moreira, "Probabilistic-based assessment of composite steel-concrete structures through an innovative framework," Steel Compos. Struct., vol. 20, no. 6, pp. 1345–1368, 2016, http://dx.doi.org/10.12989/scs.2016.20.6.1345.
http://dx.doi.org/10.12989/scs.2016.20.6... ], Dede [¹⁵15 T. Dede, "Jaya algorithm to solve single objective size optimization problem for steel grillage structures," Steel Compos. Struct., vol. 26, pp. 163–170, 2018. https://doi.org/http://dx.doi.org/10.12989/scs.2018.26.2.163.
https://doi.org/http://dx.doi.org/10.129... ] and Shariati et al. [¹⁶16 M. Shariati et al., "Application of Extreme Learning Machine (ELM) and Genetic Programming (GP) to design steel-concrete composite floor systems at elevated temperatures," Steel Compos. Struct., vol. 33, pp. 319–332, 2019. https://doi.org/https://doi.org/10.12989/scs.2019.33.3.319.
https://doi.org/https://doi.org/10.12989... ], Kaveh and Abadi [¹⁷17 A. Kaveh and A. S. M. Abadi, "Cost optimization of a composite floor system using an improved harmony search algorithm," J. Construct. Steel Res., vol. 66, no. 5, pp. 664–669, 2010, http://dx.doi.org/10.1016/j.jcsr.2010.01.009.
http://dx.doi.org/10.1016/j.jcsr.2010.01... ].

Kravanja et al. [¹⁸18 S. Kravanja, T. Žula, and U. Klanšek, "Multi-parametric MINLP optimization study of a composite I beam floor system," Eng. Struct., vol. 130, pp. 316–335, 2017, http://dx.doi.org/10.1016/j.engstruct.2016.09.012.
http://dx.doi.org/10.1016/j.engstruct.20... ] presented the optimal designs of different steel-concrete composite floor systems connected to a welded “I” section. The study was conducted by implementing structural optimization via nonlinear programming.

Pedro et al. [¹⁹19 R. L. Pedro, J. Demarche, L. F. F. Miguel, and R. H. Lopez, "An efficient approach for the optimization of simply supported steel-concrete composite I-girder bridges," Adv. Eng. Softw., vol. 112, pp. 31–45, 2017, http://dx.doi.org/10.1016/j.advengsoft.2017.06.009.
http://dx.doi.org/10.1016/j.advengsoft.2... ] studied the optimization of “I” section steel-concrete composite bridges in two steps. On the first, a model commonly adopted by bridge engineers was implemented, followed by a finite element analysis on the second to improve the optimization

Silva and Rodrigues [²⁰20 A. R. Silva and T. A. Rodrigues, "Optimized dimensioning of steel-concrete composite beams," Rev. IBRACON Estrut. Mater., vol. 12, no. 6, pp. 1428–1453, 2019, http://dx.doi.org/10.1590/s1983-41952019000600012.
http://dx.doi.org/10.1590/s1983-41952019... ] implemented the iterative method of linear sequential programming associated with the Simplex method for the design of steel-concrete composite girders, with the objective of reducing the cost of materials.

Silva et al. [²¹21 A. R. Silva, F. A. Neves, and J. B. M. Sousa, "Optimization of partially connected composite beams using nonlinear programming," Structures, vol. 25, pp. 743–759, 2020, http://dx.doi.org/10.1016/j.istruc.2020.03.007.
http://dx.doi.org/10.1016/j.istruc.2020.... ] used the sequential linear programming algorithm to optimize mixed steel and concrete beams with partial interaction. The method proved to be efficient in the optimization of the composite beams when considering different design variables.

Gervásio [²²22 H. Gervásio, “The sustainability of steel and metallic structures” in Construmetal - Lat. Am. Met. Constr. Congr., São Paulo, 2008.] classifies steel as an environmentally friendly material due to its recycling potential. However, the author stresses that 1 kg of steel produced in a blast furnace generates 2494 g of CO₂, while the same weight of steel produced with an electric arc furnace generates 462 g of CO₂.

Paya-Zaforteza et al. [²³23 I. Paya-Zaforteza, V. Yepes, A. Hospitaler, and F. González-Vidosa, "CO2-optimization of reinforced concrete frames by simulated annealing," Eng. Struct., vol. 31, no. 7, pp. 1501–1508, 2009, http://dx.doi.org/10.1016/j.engstruct.2009.02.034.
http://dx.doi.org/10.1016/j.engstruct.20... ] study the optimization of the cost and CO₂ emissions of 6 reinforced concrete plane frames via Simulated Annealing algorithm. Results indicated that the most environmentally friendly solution is only 2.77% more expensive than the cheapest solution, while the latter presented an increase of 3.80% in CO₂ emissions.

Tormen et al. [⁶6 A. F. Tormen, Z. M. C. Pravia, F. B. Ramires, and M. Kripka, "Optimization of steel-concrete composite beams considering cost and environmental impact," Steel Compos. Struct., vol. 34, pp. 409–421, 2020. https://doi.org/http://dx.doi.org/10.12989/scs.2020.34.3.409.
https://doi.org/http://dx.doi.org/10.129... ] and Santoro and Kripka [¹²12 J. F. Santoro and M. Kripka, "Minimizing environmental impact from optimized sizing of reinforced concrete elements," Comput. Concr., vol. 25, pp. 111–118, 2020.] presented studies on composite girders and, in addition to assessing the cost optimization of these elements, the authors state that the environmental impacts of using this type of girder are directly related to the degree of mechanical interaction between girders and slabs.

Despite the large number of studies on the optimization of steel-concrete composite structures available in scientific literature, research presenting both cost and environmental optimizations of systems featuring composite girders and slabs simultaneously are not observed. It is worth noting that, according to the International Energy Agency [²⁴24 International Energy Agency, Global Status Report for Buildings and Construction. 2019.], civil construction accounted for 39% of total carbon dioxide (CO₂) emissions in 2018.

This paper presents the formulation for optimizing floor systems featuring steel-concrete composite girders and slabs, with the objective of determining the structure with the lowest financial and environmental costs. The problem was solved using Genetic Algorithms implemented with the toolbox provided by the software MATLAB [²⁵25 Mathworks, Inc., Mathworks R2015a. 2015.], considering structural safety criteria prescribed in ABNT NBR 8800:2008 [²⁶26 Associação Brasileira de Norma Técnicas, Projeto de Estruturas de Aço e de Estruturas Mistas de Aço e Concreto de Edifícios – Procedimento, ABNT NBR 8800:2008, 2008.]. The formulation proposed here was validated with the example presented by Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.] and a composite floor system of an existing structure designed by conventional methods is analyzed.

2. THE PROBLEM FORMULATION

This section presents the proposed formulation for minimizing CO₂ emissions and other environmental costs of manufacturing the composite floor system shown in Figure 1, according to safety requirements for the structural materials used. The floor system is comprised of a composite slab supported by beams, a girder that supports the secondary beams parallel to the primary beams. The composite slab is molded on a trapezoidal steel deck and primary beam, girder and beams feature solid “I” sections. The shear connections are performed via stud bolts and for the structural model, the linear elastic behavior was considered.

Figure 1
Composite floor with steel profiled sheeting (Adapted from Crisinel and Marimon 2004)

The design of the composite structural elements followed the standardized procedures provided by ABNT NBR 8800:2008 [²⁶26 Associação Brasileira de Norma Técnicas, Projeto de Estruturas de Aço e de Estruturas Mistas de Aço e Concreto de Edifícios – Procedimento, ABNT NBR 8800:2008, 2008.], based on limit-state design. It’s Annex O of the standard prescribes the guidelines for the design of steel-concrete composite beams, while the design procedure for steel-concrete composite slabs is shown in Annex Q. Breda et al. [²⁸28 B. D. Breda, T. C. Pietralonga, and É. C. Alves, "Optimization of the structural system with composite beam and composite slab using Genetic Algorithm," Rev. IBRACON Estrut. Mater., vol. 13, no. 6, pp. e13602, 2020, http://dx.doi.org/10.1590/s1983-41952020000600002.
http://dx.doi.org/10.1590/s1983-41952020... ] presented a formulation for the optimization problem analyzed here. However, the analysis performed by the authors was limited to cost optimization of the slabs and primary beams.

2.1 Choice variables

The decisions variables are the individuals that change during the optimization process. In the computer program, they are inserted using a 1×7 vector, whose data are:

$x_{1}$ : Profile determination of the Gerdau [²⁹29 GERDAU. “Perfil estrutural.” https://www2.gerdau.com.br/produtos/perfil-estrutural (accessed May. 17, 2020).
https://www2.gerdau.com.br/produtos/perf... ] catalog from where the dimensions for the parallel, secondary, and main beams are obtained. The range ranges from 1 to 88 for laminated profile and 1 to 174 for welded profiles of the VS series;

$x_{2}$ : The degree of beam-slab interaction of the secondary and main beam with values from $α_{m i n}$ to 1;

$x_{3}$ : The total height of the slab and the thickness of the formwork according to the Metform [³⁰30 METFORM. “Steel Deck: a solução definitiva em lajes.” http://www.metform.com.br/ wordpress/wpcontent/ uploads/2015/05/steel_deck_metform.pdf (accessed May 17, 2020).
http://www.metform.com.br/ ... ] catalog.

$x_{4}$ : The maximum span of the slab according to the Metform [³⁰30 METFORM. “Steel Deck: a solução definitiva em lajes.” http://www.metform.com.br/ wordpress/wpcontent/ uploads/2015/05/steel_deck_metform.pdf (accessed May 17, 2020).
http://www.metform.com.br/ ... ] catalog.

$x_{5}$ : The type of formwork according to the Metform [³⁰30 METFORM. “Steel Deck: a solução definitiva em lajes.” http://www.metform.com.br/ wordpress/wpcontent/ uploads/2015/05/steel_deck_metform.pdf (accessed May 17, 2020).
http://www.metform.com.br/ ... ] catalog. The value of 1 was assigned to MF-50 and 2 to MF-75.

The values for the thickness of the steel deck are defined in accordance with the table provided by the company Metform. That are three thicknesses for the steel sheet (0.8, 0.95 and 1.25 mm) and eight total heights for each type of geometry: for MF-50, the height varies from 100 mm to 170 mm and for MF-75 from 130 mm to 200 mm. Thus, choosing one of the three steel deck thicknesses and one the eight available total heights result in twenty-four combinations.

The steel profiles are limited to the values given in table from Gerdau [²⁹29 GERDAU. “Perfil estrutural.” https://www2.gerdau.com.br/produtos/perfil-estrutural (accessed May. 17, 2020).
https://www2.gerdau.com.br/produtos/perf... ], the smallest profile is the W 150 × 13 and the largest, W 610 × 217. The steel wire mesh is defined according to stipulations from the steel deck manufacturer, and the diameter. The wires varying from Q-75 (ø3.8×ø3.8 - 150×150) to Q-138 (ø4.2×ø4.2 - 100×100). Transverse reinforcements were designed with 8 mm reinforcement bars and welded wire mesh Q-75 (ø3.8×ø3.8 - 150×150) to ensure that the minimum steel area is provided when necessary.

Figure 2 shows the cross section of the system indicating the dimensions of the profile and slab geometry that are obtained through the Gerdau [²⁹29 GERDAU. “Perfil estrutural.” https://www2.gerdau.com.br/produtos/perfil-estrutural (accessed May. 17, 2020).
https://www2.gerdau.com.br/produtos/perf... ] and Metform [³⁰30 METFORM. “Steel Deck: a solução definitiva em lajes.” http://www.metform.com.br/ wordpress/wpcontent/ uploads/2015/05/steel_deck_metform.pdf (accessed May 17, 2020).
http://www.metform.com.br/ ... ] catalog, respectively. h corresponds to the height of the web, b_f the width of the flanges, t_w the thickness of the web, t_f the thickness of the flanges, t_c the height of the concrete slab, b the effective width of the concrete slab and h_f the height of the ribs of the shaped slab steel incorporated.

Figure 2
Cross-section of the composite girder and composite slab.

2.2 Objective function

The objective function for optimizing environmental impact, given in kg of CO₂ emission, is presented in Equation 1.

M i n i m i z e C O_{2} = C O_{2 (b e a m)} + C O_{2 (f o r m w o r k)} + C O_{2 (c o n c r e t e)} + C O_{2 (m e s h)}

(1)

where CO_2(beam) corresponds to the CO₂ emissions of the steel profile, transverse reinforcement and shear connector of the primary beam and beams given by the sum of Equation 2 and 3.

C O_{2 (b e a m) V S P} = (2 + n_{b e a m}) \cdot [(ρ_{s t e e l} \cdot A_{a} \cdot L \cdot E_{s t e e l}) + (n \cdot ρ_{s t e e l} . V_{c} \cdot E_{s t e e l}) + (A_{s} \cdot l_{b} \cdot ρ_{s t e e l} \cdot E_{s t e e l})]

(2)

with the first term of the equation corresponding to the sum of beams, represented by n_beams, and two parallel primary beams, while ρ_steel is the specific mass of the steel from the profile in kg/m³, A_a is the cross-sectional area of profiled steel (m²), L is the length of the beam (m), E_steel is the CO₂ emission of steel (kgCO₂/kg), n is the number of stud bolt connectors, V_c is the volume of the stud bolt connector (m³), A_s is the area of transverse reinforcement (m²) and l_b is the anchorage length of the transverse reinforcement (m).

C O_{2 (b e a m) V P} = (V_{s t e e l} \cdot E_{s t e e l} \cdot ρ_{s t e e l}) + (n_{p} \cdot V_{c} \cdot ρ_{s t e e l} \cdot E_{s t e e l}) + (A_{s p} \cdot l_{b p} \cdot ρ_{s t e e l} \cdot E_{s t e e l})

(3)

where V_steel is the volume of the girder, perpendicular to the beams (m³), n_p is the number of stud bolt connectors on the girder, A_sp is the area of transverse reinforcement of the girder (m²) and l_bp the anchorage length of the transverse reinforcement on the girder (m).

CO_2concrete, is the CO₂ emission of concrete determined with Equation 4.

C O_{2 (c o n c r e t e)} = E_{c o n c} \cdot A_{s l a b} \cdot v_{c o n c}

(4)

where E_conc, is the CO₂ emission of concrete (kgCO₂/m³), A_slab is the rectangular area of the slab covered by the steel deck (m²) and v_conc is usage of concrete (m³/m²).

CO_2(formwork) is the emission of the steel deck determined by Equation 5.

C O_{2 (f o r m w o r k)} = A_{s l a b} \cdot p_{f o r m w o r k} \cdot E_{s d}

(5)

where p_formwork is the weight of the steel deck (kg/m²) and E_sd the CO₂ emission of the steel deck (kgCO₂/kg).

CO_2(mesh) represents the emission of the reinforcing mesh given by Equation 6.

C O_{2 (m e s h)} = A_{s l a b} \cdot p_{m e s h} \cdot E_{m e s h}

(6)

where p_mesh is the weight of the mesh (kg/m²) and E_tela is the corresponding CO₂ emission (kgCO₂/kg).

2.3 Constraints

The constraint functions are based on ABNT NBR 8800:2008 [²⁶26 Associação Brasileira de Norma Técnicas, Projeto de Estruturas de Aço e de Estruturas Mistas de Aço e Concreto de Edifícios – Procedimento, ABNT NBR 8800:2008, 2008.] Annex O design recommendations, given by Equation 7:

C = \{\begin{matrix} \frac{h_{w} / t_{w}}{5.7 \sqrt{E / f_{y k}}} - 1 \leq 0 \\ \frac{α_{m i n}}{α} - 1 \leq 0 \\ \frac{M_{s d}}{M_{r d}} - 1 \leq 0 \\ \frac{V_{s d}}{V_{r d}} - 1 \leq 0 \\ \frac{q_{s d}}{q_{r d}} - 1 \leq 0 \\ \frac{(M_{G a, S k} / W_{a, i}) + (M_{L, S k} / W_{e f, i})}{f_{y k}} - 1 \leq 0 \\ \frac{δ_{t}}{δ_{a d m}} - 1 \leq 0 \\ \frac{H_{v, S d}}{H_{v . R d}} - 1 \leq 0 \end{matrix}

(7)

where h_w is the height of the profile web (m), t_w is the web thickness (m), E is the modulus of elasticity of steel (kN/m²), f_yk the characteristic yield strength of steel of the profiles (kN/m²), α_min minimum allowable interaction between beam and slab according to ABNT NBR 8800:2008 [²⁶26 Associação Brasileira de Norma Técnicas, Projeto de Estruturas de Aço e de Estruturas Mistas de Aço e Concreto de Edifícios – Procedimento, ABNT NBR 8800:2008, 2008.], α the degree of interaction between beam and slab, M_sd the design bending moment acting on the beam (kN $\cdot$ m), M_rd the design resistance to bending moment (kN $\cdot$ m), V_sd is the design shear force acting on the structure (kN), V_rd the design resistance of shear force ( $kN$ ), q_sd the uniformly distributed live load on the slab (kN/cm²), q_rd is the live-load capacity of the slab (kN/m²), obtained from design tables provided by Metform [³⁰30 METFORM. “Steel Deck: a solução definitiva em lajes.” http://www.metform.com.br/ wordpress/wpcontent/ uploads/2015/05/steel_deck_metform.pdf (accessed May 17, 2020).
http://www.metform.com.br/ ... ], M_Ga,Sk and M_L,Sk are the design bending moments on the structure before and after concrete curing, respectively (kN $\cdot$ m), W_ef,i is the inferior elastic section modulus of the transformed section (m³), W_a,i is the inferior elastic section modulus of the steel profile (m³), δ_t is the total deflection (mm) and δ_adm is the maximum allowable deflection (mm), H_v,Sd is the design shear force acting on the slab (kN/m), H_v,Rd is the corresponding design resistance to shear force (kN/m).

3. RESULTS AND DISCUSSIONS

Two numerical examples are presented to verify the efficiency of the formulation proposed in this paper, one of which extracted from Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.] and the other corresponds to an existing structure featuring composite floor systems. The material properties common to both examples are Modulus of elasticity of steel (E): 200 GPa; Tensile strength of steel of the beams (f_yk): 345 MPa; Diameter of shear connectors (d_cs): 1.9 cm; Tensile strength of steel of the shear connectors (f_ucs): 415 MPa; Coefficient for consideration of connector grouping (R_g): 1; Coefficient for considering the position of connectors (R_p): 0.6. It is worth mentioning that, for simplicity, R_p was considered in the most unfavorable situation, that is, connectors welded on a mixed slab with ribs perpendicular to the steel profile and the distance from the half height of the web of the form rib to the face of the connector shaft less than 50 mm. The parameter chosen to measure the environmental impact was the CO₂ emission resulting from construction processes, considering the total carbon footprint generated from raw material extraction to the final product. Table 1 presents the reference values of CO₂ emissions used in this study.

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Table 1
CO₂ emission of materials

The cost of the materials was obtained by consulting manufacturers or from other scientific studies, indicated in Table 2. The prices of concrete, steel profiles and reinforcing steel mesh were reproduced from SINAPI [³²32 Sistema Nacional de Pesquisa de Custos e Índices da Construção Civil. http://www.caixa.gov.br/poder-publico/apoio-poder-publico/sinapi/Paginas/default.aspx (accessed Mar. 20, 2020).
http://www.caixa.gov.br/poder-publico/ap... ]. The cost of stud bolt connectors was obtained from Cordeiro [³³33 F. C. R. Cordeiro, “Análise de produtividade da mão-de-obra e composição de custos do serviço de execução da laje steel deck,” Undergraduate thesis, UFSC, Florianópolis, 2016.] and the cost of the steel decks was provided by the MS Estruturas Metálicas (2020) company.

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Table 2
Cost of materials

4.1 Example 1 – Fakury, Silva and Caldas

The example from Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.] presents a floor system from a commercial building located in a moderate environmental aggressiveness zone. The system features a composite slab with steel deck MF-75 of 0.95 mm thickness, 15.0 cm of height, reinforcing mesh Q-75 (ø3.8×ø3.8 – 150×150) and concrete with a compressive strength of 25 MPa, manufactured using gneiss as aggregate. The beams V1 are simply supported and comprised of the laminated profile W 310 × 28,3, while the girder V3 features the monosymmetric welded profile VSM 450 × 59, with the narrowest flange in contact with the slab. The geometries of the floor and reference cross-section are given in Figure 3 and load factors for dead and live loads, considered here before and after concrete curing, are given in Table 3.

Figure 3
Geometry of the floor system from example 1

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Table 3
Loads before concrete curing

Table 4 presents the results obtained by Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.] and results from the proposed formulation. The geometry and cross-section of the optimum solution indicated by the program are shown in Figure 4.

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Table 4
Results for example 1

Figure 4
Optimal geometry of the floor system for example 1

Results from Table 4 shows that, despite the optimized solution indicating a larger number of shear connectors and beams, the profile section selected for said beams presents a lower linear weight in comparison with the reference example, while maintaining the same height.

The slab selected for the optimized solution presents a smaller height, with reductions of height for the steel deck and the concrete layer. Since the composite beam V2 are primary and internal, the optimization procedure selected the same profile used for the beams.

Table 5 shows a comparison between CO₂ emission and cost obtained from the optimization program and from Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.].

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Table 5
CO₂ emission and cost for example 1

As shown in Table 5, the environmental impact resulting from CO₂ emission, indicates reductions in this parameter for the steel deck (16.34%), concrete (8.89%), Transverse reinforcement (11.71%), girder V3 (11.85%) and primary beam V2 (28.39%). These results may be explained by reductions of the linear weight of the girders, number of connectors, along with steel deck and concrete layer thicknesses, which tends to reduce material consumption and consequently the rate of de CO₂ emission. Since the reinforcing steel mesh used was the same for both approaches, no changes are observed for this material.

Furthermore, Table 5 also shows considerable reduction of cost when the optimized solution is implemented. The percentual reductions of cost were primary beam V2 (25.43%) and girder V3 (12.86%), transverse reinforcement (17.25%), steel deck (10.61%) and concrete (8.89%). In a general perspective, the environmental optimization program presents a reduction in cost of 10.51%.

A comparison between both responses reveals that, although the optimized alternative features a greater number of beams, the results correspond to a reduction of 12.32% and 9.11% of total cost and CO₂ emission, respectively. Table 6 shows the compressive strength influences of concrete on the environmental impact of the optimized results.

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Table 6
Results from example 1 for different values of f_ck

Results show that an increase in the compressive strength of concrete initially results in more CO₂ emission. However, at 40 MPa there is a reduction of environmental impact, followed by a tendency to increase for larger values of compressive strength. The most environmentally friendly solution corresponds to an f_ck of 20 MPa. As such, it is plausible to conclude that increases in f_ck interferes with improvements in CO₂ emission up to a limit value.

Furthermore, the lowest cost is obtained for f_ck equal to 40 MPa, implying that the financially optimal solution does not necessarily correspond to the environmentally optimal alternative. If limitations related to environmental aggressiveness are imposed, as stated by Kripakaran et al. [¹¹11 P. Kripakaran, B. Hall, and A. Gupta, "A genetic algorithm for design of moment-resisting steel frames," Struct. Multidiscipl. Optim., vol. 44, no. 4, pp. 559–574, 2011, http://dx.doi.org/10.1007/s00158-011-0654-7.
http://dx.doi.org/10.1007/s00158-011-065... ] concerning the decision-making support system and the application of MGA, a more comprehensive analysis of the results reveals that the best solution from a financial and environmental standpoint is obtained for f_ck equal to 40 MPa. Figures 5a and 5b present percentages of CO₂ emission and cost for each analyzed alternative. It is observed that the steel deck presents the highest percentage of CO₂ emission for all resistance classes of concrete, followed in most cases by profiles V1 and V2, except for f_ck values of 35 MPa, 45 MPa and 50 MPa, in which concrete presents the second highest percentage. Alternatively, Figure 5b shows the contribution of each material to the total cost of the structural system. Beams V1 and primary beam V2 figured as the most financially burdensome, followed by an alternation between girder V3 and the steel deck.

Figure 5
Optimized solution for example 1

The least expensive solution is only 1.71% cheaper than the solution corresponding to the smallest CO₂ emission, which presents a reduction of 3.57% for this parameter. As such, if a financial limit is imposed, the best possible solution features a compressive strength of concrete equal to 20 MPa.

Given the analysis of Figure 5, it is noted that a large portion of CO₂ emission is attributed to the steel from secondary beams, girders, and steel deck, reaching up to 85% of total emissions of the structure for lower f_ck values. As the compressive strength of concrete increases, emissions from this material also increase, while emissions from steel are reduced to values around 65%. Furthermore, the largest cost results from steel elements, reaching up to 90% of the total value for smaller concrete compressive strengths.

The way constraints are imposed by the program indicates the percentage of optimization attributed to each variable, such as the ratios between maximum deflection and allowable deflection (Δδ), applied loads and resistance to shear force (ΔV) and bending moment (ΔM). Figures 6a and 6b presents these ratios to SLS and ULS of the beam, primary beam, and girder profiles for example 1. The imposed constraints show that the smallest ratio corresponds to ΔM, especially for girder V3 if a compressive strength of 40 MPa is adopted for concrete. This indicated that the applied load is close to the resistance stipulated by the ULS.

Figure 6
Verification of SLS and ULS

4.2 Example 2 – Case study of the Nexem building

This example presents an application of the methodology proposed herein to the Nexem building – Nucleous of Excelence in Metallic Structures (direct translation from Portuguese), shown in Figure 7. This example is also analyzed by Breda et al. [²⁸28 B. D. Breda, T. C. Pietralonga, and É. C. Alves, "Optimization of the structural system with composite beam and composite slab using Genetic Algorithm," Rev. IBRACON Estrut. Mater., vol. 13, no. 6, pp. e13602, 2020, http://dx.doi.org/10.1590/s1983-41952020000600002.
http://dx.doi.org/10.1590/s1983-41952020... ]. The structure is located at Goiabeiras campus of the Federal University of Espírito Santo (UFES) and features a composite girder and slab system with a constructed area of 264.98 m².

Figure 7
Nexem (Breda et al. [²⁸28 B. D. Breda, T. C. Pietralonga, and É. C. Alves, "Optimization of the structural system with composite beam and composite slab using Genetic Algorithm," Rev. IBRACON Estrut. Mater., vol. 13, no. 6, pp. e13602, 2020, http://dx.doi.org/10.1590/s1983-41952020000600002.
http://dx.doi.org/10.1590/s1983-41952020... ])

According to field measurements performed by Breda et al. [²⁸28 B. D. Breda, T. C. Pietralonga, and É. C. Alves, "Optimization of the structural system with composite beam and composite slab using Genetic Algorithm," Rev. IBRACON Estrut. Mater., vol. 13, no. 6, pp. e13602, 2020, http://dx.doi.org/10.1590/s1983-41952020000600002.
http://dx.doi.org/10.1590/s1983-41952020... ], the system selected for analysis is the classroom located on the first floor, featuring steel deck MF-50 with 0.80 mm thickness, 15.0 cm of total height, reinforcing mesh Q-113 (ø 3.8 × ø 3.8 – 100 × 100) and concrete with an f_ck of 30 MPa. The internal composite beams V1 are simply supported and feature cross-section W 200 × 31.3, as shown in Figure 8.

Figure 8
Geometry of the floor system from example 2

The construction was propped, and the characteristic values of dead and live loads, along with the corresponding load factors are given in Table 7.

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Table 7
Loads after concrete curing

Table 8 shows results for the conventional and optimized design of Nexem. Regardless of the optimized design indicating the use of two additional beams V1, a reduction of cross-section geometry is observed for all profiles, resulting in less linear weight and a smaller height. The presence of additional beams also reduced the thickness of the slab.

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Table 8
Results for example 2

Results show a reduction in financial and environmental cost for most elements designed with de optimization program. The topology indicated by the program features the same steel deck type adopted for the original design of the building, but remaining components of the slab system are the major contributors for optimizing the design, namely 32% for concrete and 32.78% for the reinforcing steel mesh. Even with an increase in the number of beams V1, the program reduces the weight and cost of primary beams V2 and girder V3, by 24.16% and 15.29%, respectively.

Table 9 shows a comparison between greenhouse gas emission and cost of the optimized program and the existing structural design.

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Table 9
CO₂ emission and cost for example 2

It must be noted that, except for beams V1, which presented reduction in CO₂ emission (5.9%), every component that contributed to cost reduction also reduced environmental impact by the following percentages: 29.43% (V2), 14.19% (V3), 32% (concrete) and 32.78% (reinforcing steel mesh). Overall, the optimization program reduced environmental impact by 17.7% and cost by 17.47%. Geometries of the floor plan and the cross-section obtained with the optimized procedure are presented in Figure 9.

Figure 9
Optimal floor geometry for example 2

Table 10 and Figures 10a and 10b show the influence of concrete strength on the environmental impact of the composite system analyzed here.

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Table 10
Results from example 2 for different values of f_ck

Figure 10
Optimized solution for example 2

The table indicates the smallest environmental impact for an f_ck of 25 MPa and the cheapest solution for a compressive strength of 20 MPa. Therefore, increases in the compressive strength of concrete do not improve the optimized solution and the most financially optimum alternative does not correspond to the lowest environmental impact. The optimization program arrived at the same solution of steel deck as the original design of NEXEM, given that the steel sheet from the table used already presented the minimum dimensions.

An assessment of optimized solution concerning environmental impact and cost indicates that the difference of CO₂ emission for finding the best cost is 1.04%, smaller than what is observed for the cost of 1.15%.

Based on Figure 10a, the largest portion of CO₂ emission stems from the steel deck, with an average of 37.57%, while the most expensive item is the girder V3, corresponding, on average, to 33.64% of the total cost (see Figure 10b).

Further, steel generates the largest material consumption of the global floor system, which represents the equivalent of 76.06% of CO₂ emission and 90.22% of the total cost.

Figures 11a and 11b present the SLS and the ULS for the beam V1, primary beam V2 and girder V3. It is noted that percentages for SLS and ULS are large for the design of beam V1 and primary beam V2. Girder V3, however, presents smaller values for each limit state, especially for Δδ, that is, the design value is close to the allowable limit prescribed by the SLS.

Figure 11
Verification of SLS and ULS

4. CONCLUSIONS

This present study proposed a formulation for optimizing the design of a floor system featuring steel-concrete composite girders and slabs, with the objective of determining a structural system of minimal financial and environmental costs.

The formulation was validated by two numerical examples, the first of which originally presented by Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.] and the second corresponding to an existing structure featuring the same composite floor system in its structure, Nexem.

The first example showed that, despite the optimized design increasing the number of beams, amplifying financial and environmental costs attributed to these elements, the solution presents lighter girders and reduced the geometry of the composite slab. Overall, the solution reduced CO₂ emission by 12.32% and cost by 9.11%. If limits according to the class of environmental aggressiveness are imposed on the values of concrete strength, alternatives in accordance to studies conducted by Kripakaran et al. [¹¹11 P. Kripakaran, B. Hall, and A. Gupta, "A genetic algorithm for design of moment-resisting steel frames," Struct. Multidiscipl. Optim., vol. 44, no. 4, pp. 559–574, 2011, http://dx.doi.org/10.1007/s00158-011-0654-7.
http://dx.doi.org/10.1007/s00158-011-065... ] on a decision making support system and application of MGA, indicate an optimal solution corresponding to an f_ck of 40MPa.

In similar fashion to the first case study, results from the second example present an increase in the number of beams and lighter profiles. Consequently, the typology of the composite slab was subjected to reductions in all components except the steel deck. Overall, the optimized design reduced environmental impact by 17.7% and cost by 17.47%.

Both examples indicated a reduction in environmental impact in comparison with the original solution, since most elements adopted for the optimized design presented reductions in geometry, and consequently, in weight. It is also noted that optimizing CO₂ emission reduced the cost of the structure, indicating that structural weight is related to cost and environmental parameters.

The detailing of the cost and CO₂ emission of the materials included in the optimization shows a larger environmental impact attributed to steel elements, with more than 75% in both examples. Likewise, the largest costs also result from steel elements, reaching a value of 90% in relation to the cost of the concrete used. As such, the materials that generate the largest CO₂ emission also represent the largest portion of global costs.

In closure, both examples showed that the steel deck presents the largest percentage of environmental impact for the entire system, while primary beam and beam profiles with the same cross-section presented the largest cost. Furthermore, it was seen that increasing f_ck does not improve environmental factors, however, if standardized restrictions are imposed on this parameter, the solution corresponding to the lowest environmental impact is not necessarily the same.

ACKNOWLEDGEMENTS

The authors would like to thank Capes and Fapes for the support given to the postgraduate program in civil engineering at UFES and CNPq for the research grant provided.

Financial support: None.
Data Availability: The data that support the findings of this study are available from the corresponding author, PATA, upon reasonable request.
Erratum

In the article “Optimum design of a composite floor system considering environmental and economic impacts”, DOI number https://doi.org/10.1590/S1983-41952022000300002, published in IBRACON Structures and Materials Journal ISSN 1983-4195, v.15, n.3, e 15302, 2022, on page 1-17:

3. RESULTS AND DISCUSSIONS
Where it reads:

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Table 1
CO₂ emission of materials

It should be read:

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Table 1
CO₂ emission of materials

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³¹
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³²
Sistema Nacional de Pesquisa de Custos e Índices da Construção Civil. http://www.caixa.gov.br/poder-publico/apoio-poder-publico/sinapi/Paginas/default.aspx (accessed Mar. 20, 2020).
» http://www.caixa.gov.br/poder-publico/apoio-poder-publico/sinapi/Paginas/default.aspx
³³
F. C. R. Cordeiro, “Análise de produtividade da mão-de-obra e composição de custos do serviço de execução da laje steel deck,” Undergraduate thesis, UFSC, Florianópolis, 2016.
³⁴
M. S. Estruturas Metálicas. “Painel steel deck.” https://rms-estruturas-metalicas.webnode.com.pt/products/painel-steel-deck-apartir-de-r%24-46%2C35-m%C2%B2/ (accessed Mar. 19, 2020).
» https://rms-estruturas-metalicas.webnode.com.pt/products/painel-steel-deck-apartir-de-r%24-46%2C35-m%C2%B2/

Edited by

Editors: Mark Alexander, Guilherme Aris Parsekian

Publication Dates

Publication in this collection
22 Nov 2021
Date of issue
2022

History

Received
15 Apr 2021
Accepted
16 Sept 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Financial support: None.

[2] Data Availability: The data that support the findings of this study are available from the corresponding author, PATA, upon reasonable request.

[3] Erratum

In the article “Optimum design of a composite floor system considering environmental and economic impacts”, DOI number https://doi.org/10.1590/S1983-41952022000300002, published in IBRACON Structures and Materials Journal ISSN 1983-4195, v.15, n.3, e 15302, 2022, on page 1-17:

3. RESULTS AND DISCUSSIONS
Where it reads:

Thumbnail

Table 1
CO₂ emission of materials

It should be read:

Thumbnail

Table 1
CO₂ emission of materials

Material	Unit	CO₂ emissions	Reference	Material	Unit	CO₂ emissions	Reference
Material	Unit	(kgCO₂)	Reference	Material	Unit	(kgCO₂)	Reference
Concrete 20 MPa	m³	130.68	Santoro and Kripka [¹²12 J. F. Santoro and M. Kripka, "Minimizing environmental impact from optimized sizing of reinforced concrete elements," Comput. Concr., vol. 25, pp. 111–118, 2020.]	Steel deck	kg	26.38	Worldsteel Association [³¹31 Worldsteel Association, LCI Data for Steel Products, 2019.]
Concrete 25 MPa	m³	139.88		Steel profile	kg	11.16
Concrete 30 MPa	m³	148.28		Studbolt shear connector	kg	11.16
Concrete 35 MPa	m³	162.36		Reinforcing steel mesh	kg	19.24
Concrete 40 MPa	m³	172.77		Steel CA50, ø 8 mm, reinforcement bar	kg	19.24
Concrete 45 MPa	m³	185.32
Concrete 50 MPa	m³	216.40

Material	Unit	Cost	Reference	Material	Unit	Cost	Reference
Material	Unit	(R$)	Reference	Material	Unit	(R$)	Reference
Concrete 20 MPa	m³	295.00	SINAPI [³²32 Sistema Nacional de Pesquisa de Custos e Índices da Construção Civil. http://www.caixa.gov.br/poder-publico/apoio-poder-publico/sinapi/Paginas/default.aspx (accessed Mar. 20, 2020). http://www.caixa.gov.br/poder-publico/ap... ]	Steel CA-50, ø 8 mm, reinforcement bar	kg	5.34	SINAPI [³²32 Sistema Nacional de Pesquisa de Custos e Índices da Construção Civil. http://www.caixa.gov.br/poder-publico/apoio-poder-publico/sinapi/Paginas/default.aspx (accessed Mar. 20, 2020). http://www.caixa.gov.br/poder-publico/ap... ]
Concrete 25 MPa	m³	307.42		Stud bolt shear connector	un	11.40	Cordeiro [³³33 F. C. R. Cordeiro, “Análise de produtividade da mão-de-obra e composição de custos do serviço de execução da laje steel deck,” Undergraduate thesis, UFSC, Florianópolis, 2016.]
Concrete 30 MPa	m³	317.11		Steel deck MF-50, thickness 0.80 mm	m²	72.36	MS Estruturas Metálicas [³⁴34 M. S. Estruturas Metálicas. “Painel steel deck.” https://rms-estruturas-metalicas.webnode.com.pt/products/painel-steel-deck-apartir-de-r%24-46%2C35-m%C2%B2/ (accessed Mar. 19, 2020). https://rms-estruturas-metalicas.webnode... ]
Concrete 35 MPa	m³	329.15		Steel deck MF-50, thickness 0.95 mm	m²	80.96
Concrete 40 MPa	m³	341.57		Steel deck MF-50, thickness 1.25 mm	m²	104.54
Concrete 45 MPa	m³	384.01		Steel deck MF-75, thickness 0.80 mm	m²	83.29
Concrete 50 MPa	m³	455.43		Steel deck MF-75, thickness 0.95 mm	m²	93.18
Steel profile	kg	9.47		Steel deck MF-75, thickness 1.25 mm	m²	120.31
Reinforcing steel mesh	kg	7.96

	Load type	Load	Characteristic value [kN/m²]	Load factor
Before concrete curing	Dead	Weight of the steel structure	0.25	1.15
Before concrete curing	Live	Construction live load	1.00	1.30
After concrete curing	Dead	Weight of the steel structure	0.25	1.25
	Dead	Weight of the flooring	1.35	1.50
	Live	Serviceability live load	5.00	1.50

Information	Unit	Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.]	Optimized solution
Number of beams	un	2	3
Steel deck type	--	MF-75	MF-50
Steel deck thickness	mm	0.95	0.80
Maximum span	m	2.50	2.20
Total height of the slab	cm	15.00	11.00
Thickness of the concrete layer	cm	7.50	6.00
Reinforcing steel mesh	--	Q-75 (ø3.8-150 × 150)	Q-75 (ø3.8-150 × 150)
Profile of the beam V1	--	W 310 × 28.3	W 310 × 21
Degree of composite interaction V1	--	0.47	0.54
Total number of connectors V1	un	32	48
Transverse reinforcementV1		Q-75 (ø3.8 150 × 150) C=52	16 ø8 c/40 C=91
Profile of the primary beam V2	--	W 310 × 28.3*	W 310 × 21
Degree of composite interaction V2	un	0.47*	0.51
Total number of connectors V2	--	32*	32
Transverse reinforcementV2		Q-75 (ø3.8-150×150) C=52*	16 ø8 c/40 C=91
Profile of the girder V3	--	VSM 450 × 59	VS 450 × 51
Degree of composite interaction V3	--	0.65	0.71
Total number of connectors V3	un	32	28
Transverse reinforcement V3	--	46 ø8 c/11 C=96 6 ø8 c/40 C= 96	16 ø8 c/40 C=91

Information	Fakury et al. [²⁷27 R. Fakury, A. Silva, and R. Caldas, Dimensionamento de Elementos Estruturais de Aço e Mistos de Aço e Concreto. São Paulo: Pearson Education do Brasil, 2016.]		Optimization program
Information	Environmental impact (kgCO₂)	Cost (R$)	Environmental impact (kgCO₂)	Cost (R$)
Beams V1	481.77	4434.9	517.52	4960.56
Primary beam V2	481.77	4434.9	345.016	3307.04
Girder V3	494.71	4535.2	436.07	3951.78
Transverse reinforcement	35.7	123.7	31.52	102.36
Steel deck	1661.9	5241.38	1390.39	4685.06
Concrete	885.18	1945.39	806.5	1772.47
Reinforcing steel mesh	130.95	541.78	130.95	541.78
TOTAL	4171.98	21257.25	3657.966	19321.05

Information	Unit	20 MPa	25 MPa	30 MPa	35 MPa	40 MPa	45 MPa	50 MPa
Number of V1*	un	3	3	3	3	3	3	3
Steel deck type	--	MF-50	MF-75	MF-75	MF-75	MF-50	MF-50	MF-75
Steel deck thickness	mm	0.80	0.80	0.80	0.80	0.80	0.80	0.80
Maximum span	m	2.10	2.20	2.20	2.20	2.10	1.90	2.20
Total height of the slab	cm	11.00	14.00	14.00	14.00	11.00	11.00	14.00
Thickness of the concrete layer	cm	6.00	6.50	6.50	6.50	6.00	6.00	6.50
Reinforcing steel Mesh	--	Q-75 (ø3.8 – 150 × 150)	Q-75 (ø3.8 – 150 × 150)	Q-75 (ø3.8 – 150 × 150)	Q-75 (ø3.8 – 150 × 150)	Q-75 (ø3.8 – 150 × 150)	Q-75 (ø3.8 – 150 × 150)	Q-75 (ø3.8 – 150 × 150)
Profile V1 and V2*	--	W 310 × 21	W 310 × 21	W 310 × 21	W 310 × 21	W 310 × 21	W 310 × 21	W 310 × 21
Degree of composite interaction V1 and V2	--	0.53	0.54	0.52	0.61	0.54	0.49	0.5
Total number of connectors V1	un	48	48	48	54	48	48	48
Number of connectors V2	un	32	32	32	36	32	32	32
Transverse reinforcement V1 and V2	--	16 ø8 c/40 C=106	16 ø8 c/40 C=91	16 ø8 c/40 C=80	16 ø8 c/40 C=73	16 ø8 c/40 C=66	16 ø8 c/40 C=61	16 ø8 c/40 C=56
Profile V3*	--	VS 450 × 59	VS 450 × 51	VS 450 × 51	VS 450 × 51	VS 450 × 51	VS 450 × 51	VS 450 × 51
Degree of composite interaction	--	0.5	0.66	0.69	0.78	0.48	0.86	0.78
number of connectors	un	20	28	30	34	22	38	34
Transverse reinforcement V3	--	16 ø8 c/40 C=109	30 ø8 c/23 C=91	38 ø10 c/18 C=80	46 ø8 c/8 C=73	16 ø8 c/40 C=70	46 ø8 c/8 C=61	46 ø8 c/8 C=56
TOTAL CO₂ emission	kg	3403.84	3671.32	3718.71	3800.69	3529.68	3600.44	4102.14
TOTAL cost	R$	18780.85	19321.05	19399.16	19622.19	18459.14	18862.50	20209.63

Load type	Load	Characteristic value [kN/m²]	Load factor
Dead loads	Weight of the steel structure	0.40	1.40
Dead loads	Weight of the flooring	1.35	1.40
Live loads	Serviceability live load	3.00	1.50

Information	Unit	NEXEM	Optimized solution
Number of beams V1	un	2	4
Steel deck type	--	MF-50	MF-50
Steel deck thickness	mm	0.80	0.80
Maximum span	m	3.50	2.10
Total height of the slab	cm	15.00	11.00
Thickness of the concrete layer	cm	10.00	6.00
Reinforcing steel mesh	--	Q-113 (ø3.8- 100×100)	Q-75 (ø3.8-150×150)
Profile of the beam V1	--	W 200 × 31.3	W 200 × 15
Degree of composite interaction V1	--	0.40	0.43
Total number of connectors V1	un	24	40
Transverse reinforcementV1		6 ø8 c/31 C=79*	10 ø8 c/38 C=72
Profile of the primary beam V2	--	W 200 × 31.3*	W 200 × 15
Degree of composite interaction V2	un	0.40*	0.43
Total number of connectors V2	--	24*	20
Transverse reinforcementV2		6 ø8 c/31 C=79**	10 ø8 c/38 C=72
Profile of the girder V3	--	VS 450 × 51**	VS 400 × 44
Degree of composite interaction V3	--	0.85**	0.69
Total number of connectors V3	un	38**	26
Transverse reinforcementV3	--	12 ø8 c/40 C=86**	22 ø8 c/40 C=87

Information	NEXEM		Optimization program
Information	Environmental impact (kgCO₂)	Cost (R$)	Environmental impact (kgCO₂)	Cost (R$)
Beam V1	298.97	2797.02	281.33	2828.23
Primary beams V2	298.97	2797.02	140.66	1414.12
Girder V3	609.41	5518.81	522.92	4675.17
Transverse reinforcement	8.52	23.69	22.25	61.74
Steel deck	999.3	3267.05	999.3	3267.05
Concrete	836.86	1793.41	569.06	1219.52
Reinforcing steel mesh	156.36	646.91	105.11	434.87
TOTAL	3208.39	16843.91	2640.63	13900.70

Brasil

Brasil

Optimum design of a composite floor system considering environmental and economic impacts

Otimização de sistema de piso misto de aço e concreto considerando o impacto ambiental e econômico

Abstracts

Abstract

Resumo

1. INTRODUCTION

2. THE PROBLEM FORMULATION

2.1 Choice variables

2.2 Objective function

2.3 Constraints

3. RESULTS AND DISCUSSIONS

4.1 Example 1 – Fakury, Silva and Caldas

4.2 Example 2 – Case study of the Nexem building

4. CONCLUSIONS

ACKNOWLEDGEMENTS

Erratum

REFERENCES

Edited by

Publication Dates

History