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Neural Computing and Applications

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07-06-2016 | Original Article

Prediction of properties of self-compacting concrete containing fly ash using artificial neural network

Authors: Omar Belalia Douma, Bakhta Boukhatem, Mohamed Ghrici, Arezki Tagnit-Hamou

Published in: Neural Computing and Applications | Special Issue 1/2017

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Abstract

This paper investigates the feasibility of using artificial neural networks (ANNs) modeling to predict the properties of self-compacting concrete (SCC) containing fly ash as cement replacement. For the purpose of constructing this model, a database of experimental data was gathered from the literature and used for training and testing the model. The data used in the artificial neural network model are arranged in a format of six input parameters that cover the total binder content, fly ash replacement percentage, water–binder ratio, fine aggregates, coarse aggregates and superplasticizer. Four outputs parameters are predicted based on the ANN technique as the slump flow, the L-box ratio, the V-funnel time and the compressive strength at 28 days of SCC. To demonstrate the utility of the proposed model and improve its performance, a comparison of the ANN-based prediction model with other researcher’s experimental results was carried out, and a good agreement was found. A sensitivity analysis was also conducted using the trained and tested ANN model to investigate the effect of fly ash on SCC properties. This study shows that artificial neural network has strong potential as a feasible tool for predicting accurately the properties of SCC containing fly ash.

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Zongjin L (2011) Advanced concrete technology. Wiley, Hoboken

Ozawa K, Maekawa K, Kunishima H, Okamura H (1989) Performance of concrete based on the durability design of concrete structures. Proc Second East Asia Pacific Conf Struct Eng Constr 1:445–456

Okamura H et al (1995) Self-compacting high performance concrete. Proc Fifth EA SEC 3:2381–2388

EFNARC (2005) Specification and guidelines for self-compacting concrete. EFNARC Association House, Hampshire

Neville AM (2005) Properties of concrete, 4th edn. Pearson Education Limited, Essex, England

Wesche K (2005) Fly ash in concrete properties and performance. Rilem Repport 7:2005

Yahia A, Tanimura M, Shimabukuro A, Shimovama Y (1999) Effect of rheological parameters on self-compactability of concrete containing various mineral admixtures. In: International RILEM symposium on self-compacting concrete, pp 523–535

Kurita M, Nomura T (1998) Highly-flowable steel fiber-reinforced concrete containing fly ash. In: Malhotra VM (ed) Proceedings of the sixth CANMET/ACI international conference on fly ash, silica fume, slag, and natural pozzolans in concrete, vol 178. ACI Special Publication, pp 159–175

Miura N, Takeda N, Chikamatsu R, Sogo S (1993) Application of super workable concrete to reinforced concreted structures with difficult construction conditions. In: Zia P (ed) High performance concrete in severe environments. ACI Special Publication, USA, pp 163–186

10.

Boukhatem B, Kenai S, Tagnit-Hamou A, Ghrici M (2011) Application of new information technology on concrete: an overview. J Civ Eng Manag 17(2):248–258CrossRef

11.

Boukhatem B, Ghrici M, Kenai S, Tagnit-Hamou A (2011) Prediction of efficiency factor of ground-granulated blast-furnace slag of concrete using artificial neural network. ACI Mater J V 108(1):55

12.

Başyigit C, Akkurt I, Kilincarslan S, Beycioglu A (2010) Prediction of compressive strength of heavyweight concrete by ANN and FL models. Neural Comput Appl 19(4):507–513CrossRefMATH

13.

Severcan MH (2012) Prediction of splitting tensile strength from the compressive strength of concrete using GEP. Neural Comput Appl 21:1937–1945CrossRef

14.

Gencel O, Ozel C, Koksal F, Martinez-Barrera G, Brostow W, Polat H (2013) Fuzzy logic model for prediction of properties of fiber reinforced self-compacting concrete. Mater Sci 19(2):203–215

15.

Da Silva WRL, Štemberk P (2012) Predicting self-compacting concrete shrinkage based on a modified fuzzy logic model. Eng Mech 229:1173–1183

16.

Da Silva WRL, Štemberk P (2013) Expert system applied for classifying self-compacting concrete surface finish. Adv Eng Softw 64:47–61CrossRef

17.

Nehdi ML, Bassuoni MT (2009) Fuzzy logic approach for estimating durability of concrete. Proc ICE Constr Mater 162(2):81–92CrossRef

18.

Jin-li W, Hai-qing L (2010) Application of neural network in prediction for self-compaction concrete. Fuzzy information and engineering 2010. Springer, Berlin Heidelberg, pp 733–738CrossRef

19.

Uysal M, Tanyildizi H (2012) Estimation of compressive strength of self-compacting concrete containing polypropylene fiber and mineral additives exposed to high temperature using artificial neural network. Constr Build Mater 27(1):404–414CrossRef

20.

Siddique R, Aggarwal P, Aggarwal Y (2011) Prediction of compressive strength of self-compacting concrete containing bottom ash using artificial neural networks. Adv Eng Softw 42(10):780–786CrossRef

21.

Güneyisi E, Gesoglu M, Özbay E (2009) Evaluating and forecasting the initial and final setting times of self-compacting concretes containing mineral admixtures by neural network. Mater Struct 42(4):469–484CrossRef

22.

Zhou S, Shi J, Yang X, Lei L (2005) Application of neural network in prediction for flowing property of self-compacting concrete. J Water Resour Archit Eng 4:012

23.

Li FX, Yu QJ, Wei JX, Li JX (2011) Predicting the workability of self-compacting concrete using artificial neural network. Adv Mater Res 168:1730–1734

24.

Prasad BK, Eskandari H, Reddy BV (2009) Prediction of compressive strength of SCC and HPC with high volume fly ash using ANN. Constr Build Mater 23(1):117–128CrossRef

25.

Lippmann RP (1987) An introduction to computing with neural nets. ASSP Mag IEEE 4(2):4–22CrossRef

26.

Rumellhert D, Hinto G, Williams R (1986) Learning internal representations by error propagation. MIT Press, Cambridge

27.

Dhiyaneshwaran S, Ramanathan P, Baskar I, Venkatasubramani R (2013) Study on durability characteristics of self-compacting concrete with fly ash. Jordan J Civ Eng 7(3):342–352

28.

Bingöl AF, Tohumcu İ (2013) Effects of different curing regimes on the compressive strength properties of self compacting concrete incorporating fly ash and silica fume. Mater Des 51:12–18CrossRef

29.

Gettu R, Izquierdo J, Gomes PCC, Josa A (2002) Development of high-strength self-compacting concrete with fly ash: a four-step experimental methodology. In: Proceedings of the 27th conference on our world in concrete and structures, Paramasivam y TH Tan, Singapore, pp 217–224

30.

Güneyisi E, Gesoğlu M, Özbay E (2010) Strength and drying shrinkage properties of self-compacting concretes incorporating multi-system blended mineral admixtures. Constr Build Mater 24(10):1878–1887CrossRef

31.

Krishnapal P, Yadav RK, Rajeev C (2013) Strength characteristics of self compacting concrete containing fly ash. Res J Eng Sci ISSN 2278:9472

32.

Mahalingam B, Nagamani K (2011) Effect of processed fly ash on fresh and hardened properties of self compacting concrete. Int J Earth Sci Eng 4(5):930–940, ISSN 0974-5904

33.

Muthupriya P, Sri PN, Ramanathan MP, Venkatasubramani R (2012) Strength and workability character of self compacting concrete with GGBFS, FA and SF. Int J Emerg Trends Eng Dev 2(2):424–434, ISSN 2249-6149

34.

Nepomuceno MC, Pereira-de-Oliveira LA, Lopes SMR (2014) Methodology for the mix design of self-compacting concrete using different mineral additions in binary blends of powders. Constr Build Mater 64:82–94CrossRef

35.

Patel R (2003) Development of statistical models to simulate and optimize self-consolidating concrete mixes incorporating high volume of fly ash. Dissertation, University of Ryerson, Toronto

36.

Şahmaran M, Yaman İÖ, Tokyay M (2009) Transport and mechanical properties of self consolidating concrete with high volume fly ash. Cem Concr Compos 31(2):99–106CrossRef

37.

Siddique R (2011) Properties of self-compacting concrete containing class F fly ash. Mater Des 32(3):1501–1507CrossRef

38.

Siddique R, Aggarwal P, Aggarwal Y (2012) Influence of water/powder ratio on strength properties of self-compacting concrete containing coal fly ash and bottom ash. Constr Build Mater 29:73–81CrossRef

39.

Uysal M, Yilmaz K (2011) Effect of mineral admixtures on properties of self-compacting concrete. Cem Concr Compos 33(7):771–776CrossRef

40.

Demuth H, Beale M, Hagan M (2007) Neural network toolbox 5, user’s guide. The MathWorks Inc, Natick, p 849

41.

Zhu W, Bartos PJ (2003) Permeation properties of self-compacting concrete. Cem Concr Res 33(6):921–926CrossRef

42.

Naik TR, Kumar R, Ramme BW, Canpolat F (2012) Development of high-strength, economical self-consolidating concrete. Constr Build Mater 30:463–469CrossRef

43.

Turk K, Karatas M, Gonen T (2013) Effect of fly ash and silica fume on compressive strength, sorptivity and carbonation of SCC. KSCE J Civ Eng 17(1):202–209CrossRef

44.

Liu M (2010) Self-compacting concrete with different levels of pulverized fuel ash. Constr Build Mater 24(7):1245–1252CrossRef

45.

Yen T, Tang CW, Chang CS, Chen KH (1999) Flow behavior of high strength high performance concrete. Cem Concr Compos 21(5):413–424CrossRef

46.

Aïtcin PC (1994) The use of superplasticizers in high performance concrete. In: Malier Y (ed) High performance concrete: from material to structure. E & FN Spon, London, pp 14–33

Title: Prediction of properties of self-compacting concrete containing fly ash using artificial neural network
Authors: Omar Belalia Douma
Bakhta Boukhatem
Mohamed Ghrici
Arezki Tagnit-Hamou
Publication date: 07-06-2016
Publisher: Springer London
Published in: Neural Computing and Applications / Issue Special Issue 1/2017
Print ISSN: 0941-0643
Electronic ISSN: 1433-3058
DOI: https://doi.org/10.1007/s00521-016-2368-7

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