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Analytical Modeling and Experimental Validation of Balanced Reinforced Geopolymer Concrete Beams

Shankar H. Sanni*

Department of Civil Engineering, Basaveshwara Engineering College, Bagalkot, Karnataka, India.

Periodicity:December - February'2022
DOI : https://doi.org/10.26634/jce.12.1.18531

Abstract

Structural analysis is used to assess the behavior of engineering structures under the application of various loads. Commonly used structural analysis methods include analytical, experimental and numerical methods. The finite element method has become very popular among engineers and researchers as it is considered to be one of the best methods for solving complex engineering problems efficiently. There are various finite element software packages such as ATENA, ABAQUS, Hypermesh, Nastran and ANSYS to solve the engineering problems. Hence, in the present study ANSYS (Analysis System), finite element software is used for solving the reinforced concrete beams. The results thus obtained are verified with the experiment carried out. The experimental work highlights the study on flexural behavior of conventional and geopolymer reinforced beams with different grades of concrete namely M-30, M-40 and M-50. The test specimens was 100 x 200 x 2000 mm reinforced beams cured at room temperature. The alkaline solution used for present study was the combination of sodium silicate and sodium hydroxide solution with the ratio 2.50. The molarity used for the preparation of geoploymer solution was 12. The beams considered for the study were designed as balanced reinforced sections with percentage of reinforcement varying in the range of 1.45, 2.10 and 2.40. It was observed that the experimental values of reinforced concrete beams were in par with the results obtained with ANSYS modeling.

Keywords

Geopolymer Concrete, Molarity, Sodium Hydroxide, Sodium Silicate, ANSYS, Load-Deflection Curve.

How to Cite this Article?

Sanni, S. H. (2022). Analytical Modeling and Experimental Validation of Balanced Reinforced Geopolymer Concrete Beams. i-manager’s Journal on Civil Engineering, 12(1), 10-23. https://doi.org/10.26634/jce.12.1.18531

References

[1]. Ahmed, M. F., Nuruddin, M. F., & Shafiq, N. (2011). Compressive strength and workability characteristics of low-calcium fly ash-based self-compacting geopolymer concrete. International Journal of Civil and Environmental Engineering, 5(2), 64-70.

[2]. ASTM C642 (2021). Standard test method for density, absorption, and voids in hardened concrete. ASTM International (ASTM).

[3]. Bhikshma, V., Koti, R. M., & Srinivas, R. T. (2012). Anexperimental investigation on properties of geopolymer concrete (no cement concrete). Asian Journal of Civil Engineering (Building and Housing), 13(6), 841-853.

[4]. Bureau of Indian Standards. (1959). Indian Standard Code of practice for methods of test for strength of concrete (IS: 516-1959), New Delhi, India.

[5]. Bureau of Indian Standards. (1963a). Indian Standard Code of practice for methods of test for aggregates for concrete-mechanical properties (IS: 2386 (Part-IV)-1963), New Delhi, India.

[6]. Bureau of Indian Standards. (1963b). Indian Standard Code of practice for Specifications for admixtures for concrete (IS: 9103-1999), New Delhi, India.

[7]. Bureau of Indian Standards. (1987). Specifications for granulated slag for manufacture of Portland slag cement IS: 12089-1987, (Reaffirmed 1999), New Delhi, India.

[8]. Bureau of Indian Standards. (1989). Specifications for 43 grade ordinary Portland cement IS: 8112-1989, (Reaffirmed 1999), New Delhi, India.

[9]. Bureau of Indian Standards. (2000). Indian Standard Code of practice for plain and reinforced concrete (IS: 456-2000), New Delhi, India.

[10]. Bureau of Indian Standards. (2003). Indian Standard Code of practice for specifications for fly ash for use as pozzolana and admixture (IS: 3812-2003), New Delhi, India.

[11]. Bureau of Indian Standards. (2009). Indian Standard Code for recommended guidelines for concrete mix design (IS: 10262-2009), New Delhi, India.

[12]. Davidovits, J. (1988). Soft mineralurgy and geopolymers. In Proceeding of First International Conference on Geopolymer (pp. 25-48).

[13]. Davidovits, J. (1991). Geopolymers: Inorganic polymeric new materials. Journal of Thermal Analysis and Calorimetry, 37(8), 1633-1656. https://doi.org/10.1007/bf01912193

[14]. Davidovits, J. (1999, June). Chemistr y of geopolymeric systems, terminology. In Proceeding of Second International Conference on Geopolymer, (pp. 9-39).

[15]. Fernández-Jiménez, A., & Palomo, A. (2003). Characterisation of fly ashes. Potential reactivity as alkaline cements. Fuel, 82(18), 2259-2265. https://doi.org/10.1016/S0016-2361(03)00194-7

[16]. Fernández-Jiménez, A., Palomo, J. G., & Puertas, F. (1999). Alkali-activated slag mortars: Mechanical strength behaviour. Cement and Concrete Research, 29(8), 1313-1321.

[17]. Hardjito, D., Wallah, S. E., Sumajouw, D. M., & Rangan, B. V. (2004a). Factors influencing the compressive strength of fly ash-based geopolymer concrete. Civil Engineering Dimension, 6(2), 88-93. https://doi.org/10.9744/ced.6.2

[18]. Hardjito, D., Wallah, S. E., Sumajouw, D. M., & Rangan, B. V. (2004b). On the development of fly ashbased geopolymer concrete. Materials Journal, 101(6), 467-472.

[19]. Jayajothi, P., Kumutha, R., & Vijai, K. (2013). Finite element analysis of FRP strengthened RC beams using ANSYS. Asian Journal of Civil Engineering (BHRC), 14(4), 631-642.

[20]. Khadiranaikar, R. B., & Sanni, S. H. (2014). Variation of alkaline solutions on mechanical properties of geopolymer concrete. ICI Journal, 15(1), 24-31.

[21]. Narasimha, C., Atil, B. T., & Sanni, S. H. (1999). Performance of concrete with quarry dust as fine aggregate-An experimental study. Civil Engineering and Construction Review, 12, 19-24.

[22]. Rangan, B. V. (2006). Studies on low-calcium fly ashbased geopolymer concrete. Indian Concrete Institute, 9-17.

[23]. Rangan, B. V. (2008). Mix design and production of flyash based geopolymer concrete. The Indian Concrete Journal, 82(5), 7-15. https://doi.org/10.1007/978-81-322- 2187-6_123

[24]. Salman, W. (2009). Finite element analysis of reinforced concrete beams strengthened with CFRP in flexural. Diyala Journal of Engineering Sciences, 2(2), 88-104.

[25]. Sanni, S. H., & Khadiranaikar, R. B. (2016). Experimental Investigations of reinforced geopolymer concrete beams. ICI Journal, 15(1), 29-37.

[26]. Schmücker, M., & MacKenzie, K. J. (2005). Microstructure of sodium polysialate siloxo geopolymer. Ceramics International, 31(3), 433-437. https://doi.org/10.1016/j.ceramint.2004.06.006

[27]. Wolanski, A. J. (2004). Flexural behavior of reinforced and prestressed concrete beams using finite element analysis, (Doctoral dissertation), Marquette University, Milwaukee, WI.

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Analytical Modeling and Experimental Validation of Balanced Reinforced Geopolymer Concrete Beams

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