Machine learning-based prediction for compressive and flexural strengths of steel fiber-reinforced concrete

Abstract Steel fiber-reinforced concrete (SFRC) has a performance superior to that of normal concrete because of the addition of discontinuous fibers. The development of strengths prediction technique of SFRC is, however, still in its infancy compared to that of normal concrete because of its complexity and limited available data. To overcome this limitation, research was conducted to develop an optimum machine learning algorithm for predicting the compressive and flexural strengths of SFRC. The resulting feature impact was also analyzed to confirm the reliability of the models. To achieve this, compressive and flexural strengths data from SFRC were collected through extensive literature reviews, and a database was created. Eleven machine learning algorithms were then established based on the dataset. K-fold validation was conducted to prevent overfitting, and the algorithms were regulated. The boosting- and tree-based models had the optimal performance, whereas the K-nearest neighbor, linear, ridge, lasso regressor, support vector regressor, and multilayer perceptron models had the worst performance. The water-to-cement ratio and silica fume content were the most influential factors in the prediction of compressive strength of SFRC, whereas the silica fume and fiber volume fraction most strongly influenced the flexural strength. Finally, it was found that, in general, the compressive strength prediction performance was better than the flexural strength prediction performance, regardless of the machine learning algorithm.

[1]  Hyun-Do Yun,et al.  Combined effects of steel fiber and coarse aggregate size on the compressive and flexural toughness of high-strength concrete , 2018 .

[2]  M. J. Shannag,et al.  Effect of Steel Fibers on Flexural Behavior of Normal and High Strength Concrete , 2014 .

[3]  K. Sathiyakumari,et al.  Prediction of the Compressive Strength of High Performance Concrete Mix using Tree Based Modeling , 2010 .

[4]  Panagiotis G. Asteris,et al.  A novel artificial intelligence technique to predict compressive strength of recycled aggregate concrete using ICA-XGBoost model , 2020, Engineering with Computers.

[5]  Ron Kohavi,et al.  A Study of Cross-Validation and Bootstrap for Accuracy Estimation and Model Selection , 1995, IJCAI.

[6]  Şemsi Yazıcı,et al.  Effect of aspect ratio and volume fraction of steel fiber on the mechanical properties of SFRC , 2007 .

[7]  Emadaldin Mohammadi Golafshani,et al.  Machine learning study of the mechanical properties of concretes containing waste foundry sand , 2020 .

[8]  Kyoung-Kyu Choi,et al.  Flexural Performance Characteristics of Amorphous Steel Fiber-Reinforced Concrete , 2014 .

[9]  Puneet Gupta,et al.  Can the compressive strength of concrete be estimated from knowledge of the mixture proportions?: New insights from statistical analysis and machine learning methods , 2019, Cement and Concrete Research.

[10]  Osman Şimşek,et al.  Effects of super plasticizer and curing conditions on properties of concrete with and without fiber , 2008 .

[11]  L. Hsu,et al.  Stress-strain behavior of steel-fiber high-strength concrete under compression , 1994 .

[12]  Ananth Ramaswamy,et al.  Mechanical Properties of Steel Fiber-Reinforced Concrete , 2007 .

[13]  Ramzi Taha,et al.  The effect of the mineralogy of coarse aggregate on the mechanical properties of high-strength concrete , 2006 .

[14]  Theodore E. Matikas,et al.  Effects of Fibre Geometry and Volume Fraction on the Flexural Behaviour of Steel‐Fibre Reinforced Concrete , 2011 .

[15]  David J. Leinweber,et al.  Stupid Data Miner Tricks , 2007 .

[16]  Shehab Mourad,et al.  Evaluation of mechanical properties of steel fiber reinforced concrete with different strengths of concrete , 2018 .

[17]  Tuan Nguyen,et al.  Deep neural network with high‐order neuron for the prediction of foamed concrete strength , 2018, Comput. Aided Civ. Infrastructure Eng..

[18]  Kasım Mermerdaş,et al.  Effect of silica fume and steel fiber on the mechanical properties of the concretes produced with cold bonded fly ash aggregates , 2013 .

[19]  Jeffrey W. Bullard,et al.  Machine learning can predict setting behavior and strength evolution of hydrating cement systems , 2019, Journal of the American Ceramic Society.

[20]  P.S.M. Thilakarathna,et al.  Embodied carbon analysis and benchmarking emissions of high and ultra-high strength concrete using machine learning algorithms , 2020 .

[21]  Cengiz Duran Atiş,et al.  Properties of steel fiber reinforced fly ash concrete , 2009 .

[22]  Togay Ozbakkaloglu,et al.  Mechanical and durability properties of high-strength concrete containing steel and polypropylene fibers , 2015 .

[23]  Wei Dongfang,et al.  Machine learning-based compressive strength prediction for concrete: An adaptive boosting approach , 2020, Construction and Building Materials.

[24]  Hyun-Do Yun,et al.  Effects of Curing Age and Fiber Volume Fraction on Flexural Behavior of High-Strength Steel Fiber-Reinforced Concrete , 2016 .

[25]  Guowei Ma,et al.  XGBoost algorithm-based prediction of concrete electrical resistivity for structural health monitoring , 2020 .

[26]  Ali Deihimi,et al.  Experimental study and modeling of fiber volume effects on frost resistance of fiber reinforced concrete , 2018 .

[27]  Kenneth Jae T. Elevado COMPRESSIVE STRENGTH MODELLING OF CONCRETE MIXED WITH FLY ASH AND WASTE CERAMICS USING k-NEAREST NEIGHBOR ALGORITHM , 2018, International Journal of GEOMATE.

[28]  Ivan Nunes da Silva,et al.  Artificial Neural Networks , 2017 .

[29]  Manu Santhanam,et al.  Mechanical properties of high strength concrete reinforced with metallic and non-metallic fibres , 2007 .

[30]  P. Song,et al.  Mechanical properties of high-strength steel fiber-reinforced concrete , 2004 .

[31]  Hyun-ho Lee,et al.  Characteristic Strength and Deformation of SFRC Considering Steel Fiber Factor and Volume fraction , 2004 .

[32]  Eunsoo Choi,et al.  Flexural capacity of fiber reinforced concrete with a consideration of concrete strength and fiber content , 2017 .

[33]  Surendra M. Gupta,et al.  Support Vector Machines based Modelling of Concrete Strength , 2008 .

[34]  Jui-Sheng Chou,et al.  Enhanced artificial intelligence for ensemble approach to predicting high performance concrete compressive strength , 2013 .

[35]  B. K. Raghu Prasad,et al.  Fracture energy and softening behavior of high-strength concrete , 2002 .

[36]  Young Soo Yoon,et al.  Flexural response of steel-fiber-reinforced concrete beams: Effects of strength, fiber content, and strain-rate , 2015 .

[37]  Sunday O. Olatunji,et al.  Performance Comparison of SVM and ANN in Predicting Compressive Strength of Concrete , 2014 .

[38]  Juhong Han,et al.  Effects of steel fiber length and coarse aggregate maximum size on mechanical properties of steel fiber reinforced concrete , 2019, Construction and Building Materials.

[39]  Park Seung-Bum,et al.  An Experimental Study on the Mechanical Properties and Long-Term Deformations of High-Strength Steel Fiber Reinforced Concrete , 2006 .

[40]  B. Rajagopalan,et al.  A comparison of machine learning methods for predicting the compressive strength of field-placed concrete , 2019, Construction and Building Materials.

[41]  Jin-Kook Kim,et al.  Flexural and shear behaviour of high-strength SFRC beams without stirrups , 2019, Magazine of Concrete Research.

[42]  V. Mallikarjuna Reddy,et al.  Effect of w/c ratio on workability and mechanical properties of high strength Self Compacting Concrete (M70 grade) , 2014 .

[43]  M. Shoukath Ali,et al.  Effect of super plasticizer on the properties of medium strength concrete prepared with coconut fiber , 2018, Construction and Building Materials.

[44]  Fatih Altun,et al.  Combined effect of silica fume and steel fiber on the mechanical properties of high strength concretes , 2008 .

[45]  Jui-Sheng Chou,et al.  Concrete compressive strength analysis using a combined classification and regression technique , 2012 .

[46]  İlker Bekir Topçu,et al.  Prediction of compressive strength of concrete containing fly ash using artificial neural networks and fuzzy logic , 2008 .

[47]  Prakash S. Pajgade,et al.  STRENGTH APPRAISAL OF ARTIFICIAL SAND AS FINE AGGREGATE IN SFRC , 2010 .

[48]  Jui-Sheng Chou,et al.  Machine learning in concrete strength simulations: Multi-nation data analytics , 2014 .

[49]  Mahmoud Nili,et al.  Property assessment of steel–fibre reinforced concrete made with silica fume , 2012 .

[50]  Young Soo Yoon,et al.  Predicting the post-cracking behavior of normal- and high-strength steel-fiber-reinforced concrete beams , 2015 .

[51]  Dong Joo Kim,et al.  Influence of sand to coarse aggregate ratio on the interfacial bond strength of steel fibers in concrete for nuclear power plant , 2012 .

[52]  M. Nili,et al.  Combined effect of silica fume and steel fibers on the impact resistance and mechanical properties of concrete , 2010 .

[53]  Young-Hun Oh Evaluation of Flexural Strength for Normal and High Strength Concrete with Hooked Steel Fibers , 2008 .

[54]  Halil Ibrahim Erdal Two-level and hybrid ensembles of decision trees for high performance concrete compressive strength prediction , 2013, Eng. Appl. Artif. Intell..

[55]  Claudia P. Ostertag,et al.  Influence of matrix cracking and hybrid fiber reinforcement on the corrosion initiation and propagation behaviors of reinforced concrete , 2018 .