Bonding Performance for Lightweight Concrete: A Review

https://doi.org/10.24237/djes.2020.13408

Authors

  • Rafal Ahmed Department of Civil Engineering, College of Engineering, University of Diyala, 32001 Diyala, Iraq
  • Suhad M. Abed Department of Civil Engineering, College of Engineering, University of Diyala, 32001 Diyala, Iraq

Keywords:

Bond strength, Light weight concrete, Aerated concrete, Pull out test and Beam end test

Abstract

Nowadays, lightweight concrete become popular among construction companies due to its physical characteristic such as sound and thermal insulation, lightweight, cost and environmental saving, self-levelling…etc., which make it an attractive choice as a building material. However, this concrete face many constructional obstacles due to the lack of adequate and sufficient constructional information about the nature of this concrete. This requires great caution when use it for structural purposes. Among these great constraints, for example, is the weak characteristic of the bond between this concrete and reinforcing steel. Therefore, in order to get rid of these defects of concrete and make it usable in various construction sectors, this paper summarizes researchers works concerning bond behavior between light weight concrete and reinforcing bars , the variable influencing bond behavior such as; concrete type, rebar type and diameter, W/C ratio, and adding fibres. And results collected from experimental work with most important conclusions.

Downloads

Download data is not yet available.

References

Van Liere, J. R. (1965). The use of an epoxy resin in lightweight concrete-reinforcement bond (Doctoral dissertation, University of Wyoming).

Orangun, C. O. (1967). The bond resistance between steel and lightweight-aggregate (Lytag) concrete. Building Science, 2(1), 21-28.

Collepardi, M., & Corradi, M. (1979). Influence of naphthalene-sulfonated polymer based Superplasticizers on the strength of ordinary and lightweight concretes. Special Publication, 62, 315-336.

Regan, P. E. (1979). Shear in reinforced aerated concrete. International Journal of Cement Composites and Lightweight Concrete, 1(2), 47-61.

Weigler, H., & Karl, S. (1980). Structural lightweight aggregate concrete with reduced density—lightweight aggregate foamed concrete. International Journal of Cement Composites and Lightweight Concrete, 2(2), 101104.

Mor, A. (1993). Steel-concrete bond in high-strength lightweight concrete. Materials Journal, 89(1), 76-82.

Clarke, J. L., & Birjandi, F. K. (1993). Bond strength tests for ribbed bars in lightweight aggregate concrete. Magazine of Concrete Research, 45(163), 79-87.

Khanbilvardi, R., & Afshari, S. (1995). Sludge ash as fine aggregate for concrete mix. Journal of environmental engineering, 121(9), 633-638.

Ghavami, K. (1995). Ultimate load behaviour of bamboo-reinforced lightweight concrete beams. Cement and concrete composites, 17(4), 281-288.

Alduaij, J., Alshaleh, K., Haque, M. N., & Ellaithy, K. (1999). Lightweight concrete in hot coastal areas. Cement and Concrete Composites, 21(5-6), 453-458.

Campione, G., Cucchiara, C., La Mendola, L., & Papia, M. (2005). Steel–concrete bond in lightweight fiber reinforced concrete under monotonic and cyclic actions, Engineering Structures, 27(6), 881-890.

Teo, D. C. L., Mannan, M. A., Kurian, V. J., & Ganapathy, C. (2007). Lightweight concrete made from oil palm shell (OPS): Structural bond and durability properties. Building and environment, 42(7), 2614-2621.

El Zareef, M., & Schlaich, M. (2008). Bond behaviour between GFR bars and infra-lightweight concrete. Tailor Made Concrete Structures, 721-727.

Hossain, K. M. A. (2008). Bond characteristics of plain and deformed bars in lightweight pumice concrete. Construction and Building Materials, 22(7), 1491-1499.

Tang, W. C., Lo, T. Y., & Balendran, R. V. (2008). Bond performance of polystyrene aggregate concrete (PAC) reinforced with glass-fibre-reinforced polymer (GFRP) bars. Building and Environment, 43(1), 98-107.

Lachemi, M., Bae, S., Hossain, K. M. A., & Sahmaran, M. (2009). Steel–concrete bond strength of lightweight self-consolidating concrete. Materials and Structures, 42(7), 1015-1023.

Tanyildizi, H. (2009). Fuzzy logic model for the prediction of bond strength of high-strength lightweight concrete. Advances in Engineering Software, 40(3), 161169.

Yang, K. H., Song, J. K., & Lee, J. S. (2010). Properties of alkali-activated mortar and concrete using lightweight aggregates. Materials and structures, 43(3), 403-416.

Pul, S. (2010). Loss of concrete-steel bond strength under monotonic and cyclic loading of lightweight and ordinary concretes. Iranian Journal of Science and Technology, 34(B4), 397.

Sancak, E., Simsek, O., & Apay, A. C. (2011). A comparative study on the bond performance between rebar and structural lightweight pumice concrete with/without admixture. International Journal of Physical Sciences, 6(14), 3437-3454.

Ayudhya, B. I. N., & Ungkoon, Y. (2011). Bond strength of fiber reinforced polymer (FRP) bars in autoclaved aerated concrete (AAC). In Advances in FRP Composites in Civil Engineering (pp. 585-588). Springer, Berlin, Heidelberg.

Karahan, O., Hossain, K. M., Ozbay, E., Lachemi, M., & Sancak, E. (2012). Effect of metakaolin content on the properties self-consolidating lightweight concrete. Construction and Building Materials, 31, 320325.

Gunasekaran, K., Annadurai, R., & Kumar, P. S. (2012). Long term study on compressive and bond strength of coconut shell aggregate concrete. Construction and Building Materials, 28(1), 208-215.

Yang, W. J., Yu, J., & Wang, Y. (2012). Study on the effect of bond-anchoring factor on bond behavior between deformed bar and shale ceramic concrete. In Advanced Materials Research (Vol. 403, pp. 444-448). Trans Tech Publications.

Güneyisi, E., Gesoğlu, M., & İpek, S. (2013). Effect of steel fiber addition and aspect ratio on bond strength of cold-bonded fly ash lightweight aggregate concretes. Construction and Building Materials, 47, 358365.

Prince, M. J. R., & Singh, B. (2013). Bond behaviour of deformed steel bars embedded in recycled aggregate concrete. Construction and Building Materials, 49, 852862.

Wu, X., Wu, Z., Zheng, J., & Zhang, X. (2013). Bond behavior of deformed bars in self-compacting lightweight concrete subjected to lateral pressure. Magazine of Concrete Research, 65(23), 1396-1410.

Ramezani, M., Vilches, J., & Neitzert, T. (2013). Pullout behavior of galvanized steel strip in foam concrete. International Journal of Advanced Structural Engineering, 5(1), 24.

Kim, D. J., Kim, M. S., Yun, G. Y., & Lee, Y. H. (2013). Bond strength of steel deformed rebars embedded in artificial lightweight aggregate concrete. Journal of Adhesion Science and Technology, 27(5-6), 490-507.

Van Rooyen, A. S. (2013). Structural lightweight aerated concrete (Doctoral dissertation, Stellenbosch: Stellenbosch University).

Uygunoğlu, T., Brostow, W., Gencel, O., & Topcu, I. B. (2013). Bond strength of polymer lightweight aggregate concrete. Polymer Composites, 34(12), 2125-2132.

Carmo, R. N. F., Costa, H., & Bento, G. (2014). Experimental investigation of bond stress and deformations in LWAC ties reinforced with GFRP bars. Strain, 50(4), 318-333.

Bogas, J. A., Gomes, M. G., & Real, S. (2014). Bonding of steel reinforcement in structural expanded clay lightweight aggregate concrete: the influence of failure mechanism and concrete composition. Construction and Building Materials, 65, 350-359.

Rahim, J. A., Hamzah, S. H., & Hamidah, M. S. (2014). Bonding Strength of Expanded Polystyrene (EPS) BeadsEnhanced with Steel Fiber in Reinforced Lightweight Concrete (LWC). In Applied Mechanics and Materials (Vol. 661, pp. 100-105). Trans Tech Publications.

Maree, A. F., & Riad, K. H. (2014). Analytical and experimental investigation for bond behaviour of newly developed polystyrene foam particles’ lightweight concrete. Engineering Structures, 58, 1-11.

Zhang, D., & Yang, W. (2014). Experimental research on bond behaviors between shale ceramsite lightweight aggregate concrete and bars through pullout tests. Journal of Materials in Civil Engineering, 27(9), 06014030.

Zhou, J., Liu, H. N., Ma, S., Li, J. J., & Hou, H. T. (2014). Bond properties of ceramic concrete reinforced by bamboo bar. In Applied Mechanics and Materials (Vol. 477, pp. 920-925). Trans Tech Publications.

Mo, K. H., Alengaram, U. J., Visintin, P., Goh, S. H., & Jumaat, M. Z. (2015). Influence of lightweight aggregate on the bond properties of concrete with various strength grades. Construction and Building Materials, 84, 377-386.

Mo, K. H., Alengaram, U. J., & Jumaat, M. Z. (2016). Bond properties of lightweight concrete–a review. Construction and Building Materials, 112, 478496.

Ali, A., Iqbal, S., Holschemacher, K., & Bier, T. A. (2016). Effect of fibers on bond performance of lightweight reinforced concrete. Periodica Polytechnica. Civil Engineering, 60(1), 97.

Nindyawati and Baiq, S. U. (2016). Bond Strength of Bamboo Reinforcement in Light-weight Concrete. Journal of Civil Engineering and Architecture, vol. 10, pp 417-420.

de Villiers, J. P., van Zijl, G. P., & van Rooyen, A. S. (2017). Bond of deformed steel reinforcement in lightweight foamed concrete. Structural Concrete, 18(3), 496-506.

Mo, K. H., Goh, S. H., Alengaram, U. J., Visintin, P., & Jumaat, M. Z. (2017). Mechanical, toughness, bond and durability-related properties of lightweight concrete reinforced with steel fibres. Materials and Structures, 50(1), 46.‏

Al-Shannag, M. J., & Charif, A. (2017). Bond behavior of steel bars embedded in concretes made with natural lightweight aggregates. Journal of King Saud University-Engineering Sciences, 29(4), 365-372.‏

Mo, K. H., Yeap, K. W., Alengaram, U. J., Jumaat, M. Z., & Bashar, I. I. (2018). Bond strength evaluation of palm oil fuel ash-based geopolymer normal weight and lightweight concretes with steel reinforcement. Journal of adhesion science and Technology, 32(1), 19-35.‏

Zhao, M., Zhang, X., Yan, K., Fei, T., & Zhao, S. (2018). Bond performance of deformed rebar in steel fiber reinforced lightweight-aggregate concrete affected by multi-factors. Civil Engineering Journal, (3).

Nadir, Y., & Sujatha, A. (2018). Bond strength determination between coconut shell aggregate concrete and steel reinforcement by pull-out test. Asian Journal of Civil Engineering, 19(6), 713-723.‏

Abbas, A. N., Shihab, L. A., & Yaqoob, Y. T. (2019). BOND STRENGTH OF LIGHT-WEIGHT CONCRETE PULL-OUT SPECIMENS CONTAIN STEEL FIBERS. Journal of Engineering and Sustainable Development, 22(02 Part-2), 123-132.

Liu, X., Liu, Y., Wu, T., & Wei, H. (2020). Bond-slip properties between lightweight aggregate concrete and rebar. Construction and Building Materials, 255, 119355.

Doostmohamadi, A., Karamloo, M., & Afzali-Naniz, O. (2020). Effect of polyolefin macro fibers and handmade GFRP anchorage system on improving the bonding behavior of GFRP bars embedded in self-compacting lightweight concrete. Construction and Building Materials, 253, 119230.‏

Li, S., & Song, C. (2020). Experimental research on bond anchorage performance of 1860-grade high-strength steel strands and lightweight aggregate concrete. Construction and Building Materials, 235, 117482.‏

Hoque, M. M., Islam, M. N., Islam, M., & Kader, M. A. (2020). Bond behavior of reinforcing bars embedded in concrete made with crushed clay bricks as coarse aggregates. Construction and Building Materials, 244, 118364.‏

Published

2020-12-09

How to Cite

[1]
R. Ahmed and S. M. Abed, “Bonding Performance for Lightweight Concrete: A Review”, DJES, vol. 13, no. 4, pp. 58–70, Dec. 2020.

Issue

Diyala Journal of Engineering Sciences Vol.13, No.4, December 2020

Section

Original Articles
Copyright & Licensing

Copyright (c) 2020 Rafal Ahmed, Suhad M. Abed

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Crossref
Scopus
Google Scholar
Europe PMC