Advanced search
Publication Cover
Journal of Adhesion Science and Technology Volume 33, 2019 - Issue 14
Submit an article Journal homepage
350
Views
21
CrossRef citations to date
0
Altmetric
Article

Influence of fibers on bond strength of concrete exposed to elevated temperature

Alwyn VargheseDepartment of Civil Engineering, Karunya University, Coimbatore, India; View further author information
,
Anand NDepartment of Civil Engineering, Karunya University, Coimbatore, India; Correspondence[email protected]
ORCID Iconhttp://orcid.org/0000-0001-7643-9747View further author information
ORCID Icon,
Prince Arulraj GDepartment of Civil Engineering, Karunya University, Coimbatore, India; View further author information
&
U. Johnson AlengaramCentre for Innovative Construction Technology (CICT), Department of Civil Engineering, Faculty of Engineering, University of Malaya, Kuala Lumpur, MalaysiaView further author information
Pages 1521-1543 | Received 27 Nov 2018, Accepted 28 Mar 2019, Published online: 26 Apr 2019

References

  • Khoury GA. Effect of fire on concrete and concrete structures. Prog Struct Engng Mater. 2000;2:429–447.
  • Behnood A, Ghandehari M. Comparison of compressive and splitting tensile strength of high-strength concrete with and without polypropylene fibers heated to high temperatures. Fire Saf J. 2009;44:1015–1022.
  • Georgali B, Tsakiridis PE. Microstructure of fire-damaged concrete. A case study. Cem Concr Compos. 2005;27:255–259.
  • Sukontasukkul P, Worachet P, Smith S. Post-crack (or post-peak) flexural response and toughness of fiber reinforced concrete after exposure to high temperature. Construction Build Mater. 2010;24:1967–1974.
  • Anand N, Arulraj GP. Effect of grade of concrete on the performance of self-compacting concrete beams subjected to elevated temperatures. Fire Technol. 2014;50:1269–1284.
  • Morley PD. "Effects of elevated temperature on bond in reinforced concrete." University of Edinburgh, 1982.
  • Lublóy É, György BL. Temperature effects on bond between concrete and reinforcing steel. Zbornik Gfs.. 2014;30:27–35.
  • Poon CS, Shui ZH, Lam L. Compressive behavior of fiber reinforced high-performance concrete subjected to elevated temperatures. Cem Concr Res. 2004;34:2215–2222.
  • Suhaendi SL, Horiguchi T. Effect of short fibers on residual permeability and mechanical properties of hybrid fibre reinforced high strength concrete after heat exposition. Cem Concr Res. 2006;36:9672–1678.
  • ACE Committee 544. State-of-the-art report on fiber reinforced concrete. ACI Concr Int. 1982;4:9–30.
  • Morley PD, Royles R. Response of the bond in reinforced concrete to high temperatures. Mag Concr Res. 1983;35:67–74.
  • ACI Committee 408. Bond Stress- the state of the art. ACI J. 1966;63;1161–1188.
  • Tanyildizi H. Effect of temperature, carbon fibers, and silica fume on the mechanical properties of lightweight concretes. New Carbon Mater. 2008;23:339–344.
  • Bhat T, Chevali V, Liu X. Fire structural resistance of basalt fiber composite. Compos Part A Appl Sci Manuf. 2015;71:107–115.
  • Feng W, Lu Z. Effect of elevated temperature on the mechanical properties of basalt fibers and BFRP plates. Proceedings of the 6th Asia-Pacific Conference on FRP in Structures; 2017; Singpore; 156–157.
  • Abbasi A, Hogg PJ. Temperature and environmental effects on glass fibre rebar: modulus, strength and interfacial bond strength with concrete. Compos Part B Eng. 2005;36:394–404.
  • Kalifa P, Chene G, Galle C. High-temperature behavior of HPC with polypropylene fibres: From spalling to microstructure. Cem Concr Res. 2001;31:1487–1499.
  • Khoury GA, Willoughby B. Polypropylene fibers in heated concrete. Part 1: molecular structure and materials behavior. Mag Concr Res. 2008;60:125–136.
  • Haddad RH, Al-Saleh RJ, Al-Akhras NM. Effect of elevated temperature on bond between steel reinforcement and fiber reinforced concrete. Fire Saf J. 2008;43:334–343.
  • Faiyadh FI, Al-Ausi MA. Effect of elevated temperature on splitting tensile strength of fibre concrete. Int J Cem Compos Lightweight Concr. 1989;11:175–178. Aug 1
  • Mallick PK. Fiber-reinforced composites: materials, manufacturing, and design. USA: CRC press;2007
  • Mingchao W, Zuoguang Z, Yubin L, et al. Chemical durability and mechanical properties of alkali-proof basalt fiber and its reinforced epoxy composites. J Reinforced Plastics Compos. 2008;27:393–407.
  • Li XE. Study on thermal resistance of basalt filament yarn. AMR. 2011;146:666–669.
  • Sim J, Park C, Moon DY. Characteristics of basalt fiber as a strengthening material for concrete structures. Compos Part B Eng. 2005;36:504–512.
  • Singha K. A short review on basalt fiber. Int J Text Sci. 2012;1:19–28.
  • Chen B, Liu J. Residual strength of hybrid-fiber-reinforced high-strength concrete after exposure to high temperatures. Cem Concr Res. 2004;34:1065–1069.
  • Nahar S, Khan RA, Dey K. Comparative studies of mechanical and interfacial properties between jute and E-glass fiber-reinforced polypropylene composites. J Reinforced Plastics Compos. 2010;29:1078–1088.
  • Gupta VB, Vk K. Manufactured fibre technology, 457–479. London (UK): Chapman & Hall;1997
  • Bergman TL, Incropera FP, Lavine AS, et al. Fundamentals of heat and mass transfer. 7th ed. USA: John Wiley & Sons;2011
  • Aulia TB. Effects of polypropylene fibers on the properties of high-strength concretes. Germany: Institutes for Massivbau and Baustoffechnologi, University Leipzig; 2002, Lacer 7.
  • Indian Standard Methods of Testing Bond in Reinforced Concrete Part 1 Pull-Out Test (2007) Bureau of Indian Standards, Manak Bhavan, New Delhi.
  • FIB Bulletin No. 10. Bond of Reinforcement in Concrete, State of the Art. Report prepared by Task Group Bond Models, former CEB, Task Group 5.2.CH-1015, Lausanne, 2000.
  • Sfikas IP, Trezos KG. Effect of composition variations on bond properties of self compacting concrete specimens. Constr Build Mater. 2013;41:252–262.
  • Foroughi A, Dilmaghani S, Famili H. Bond strength of reinforcement steel in self-compacting concrete. Int J Civ Eng. 2008;6:24–33.
  • Noumowe AN, Clastres P, Debicki G, Costaz J-L. Transient heating effect on high strength concrete. Nucl Eng Des. 1996;166:99–108.
  • Royles R, Morley PD. Further responses of the bond in reinforced concrete to high temperatures. Mag Concr Res. 1983;35:157–163.
  • Morley PD, Royles R. The influence of high temperature on the bond in reinforced concrete. Fire Saf J. 1980;2:243–255.
  • Arioz O. Effects of elevated temperatures on properties of concrete. Fire Saf J. 2007;42:516–522.
  • Diederichs U, Schneider U. Bond strength at high temperatures. Mag Concr Res. 1981;33:75–84.
  • Chan YN, Peng GF, Anson M. Residual strength and pore structure of high-strength concrete and normal strength concrete after exposure to high temperatures. Cem Concr Compos. 1999;21:23–27.
  • Ezeldin A, Balaguru P. Bond behavior of normal and high-strength fiber reinforced concrete. Mater J. 1989;86:515–524.
  • Jiang C, Fan K, Wu F, et al. Experimental study on the mechanical properties and microstructure of chopped basalt fibre reinforced concrete. Mater Des. 2014;58:187–193.
  • Mallick PK. Fiber-Reinforced Composites: Materials, Manufacturing and Design. 3rd Edition. London, UK: CRC Press; 2007
  • Wei B, Cao H, Song S. RETRACTED: environmental resistance and mechanical performance of basalt and glass fibers. Mater Sci Eng A. 2010;527:4708–4715.
  • Yamasaki Y, Masuda Y, Tanano H, et al. Fundamental properties of continuous fiber bars. International Concrete Abstracts Portal (ACI). 1993;138:715–730.
  • Burgoyne CJ. Aramid fibers for civil engineering applications. In: Doran DK, editor. Construction materials reference book. UK: Butterworth-Heinemann; 1992
  • Derombise G, Schoors LVV, Messou MF, et al. Influence of finish treatment on the durability of aramid fibers aged under an alkaline environment. J Appl Polym Sci. 2010;117:888–898.
  • Hannant DJ. Durability of polypropylene fibers in Portland cement-based composites: eighteen years of data. Cem Concr Res. 1998;28:1809–1817.
  • Toledo Filho RD, Sanjuan MA. Effect of low modulus sisal and polypropylene fibre on the free and restrained shrinkage of mortars at early age. Cem Concr Res. 1999;29:1597–1604.
  • Gemert DV, Czarnecki L, Lukowski P, et al. Cement concrete and concrete–polymer composites. Cem Concr Res. 2005;27:926–933.
  • Schulze J. Influence of water-cement ratio and cement content on the properties of polymer-modified mortars. Cem Concr Res. 1999;29:909–915.
  • Landucci G, Rossi F, Nicolella C, et al. Design and testing of innovative materials for passive fire protection. Fire Saf J. 2009;44:1103–1109.
  • Nishida A, Yamazaki N, Inoue H, et al. Study on the Properties of High Strength Concrete with Short Polypropylene Fibres for Spalling Resistance. In Sakai K., Banthia N., Gjorv OE. editors. proceedings of the Symposium Concrete under Severe Conditions 2; 1995, Saporo, Japan; 1141–1150.
  • Bošnjak J, Ožbolt J, Hahn R. Permeability measurement on high strength concrete without and with polypropylene fibers at elevated temperatures using a new test setup. Cem Concr Res. 2013;53:104–111.
  • Özbay E, Türker HT, Balçıkanlı M, et al. Effect of Fiber Types and Elevated Temperatures on the Bond Characteristic of Fiber Reinforced Concretes. Wor Acad Sci. Eng. Technol. Int J Civ Environ Struct Construction Archit Eng. 2015;9:549–553.
  • Ozawa M, Morimoto H. Effects of various fibers on high-temperature spalling in high-performance concrete. Construction Build Mater. 2014;71:83–92.
  • Khoury GA. Polypropylene fibers in heated concrete. Part 2: pressure relief mechanisms and modelling criteria. Mag Concr Res. 2008;60:189–204.
  • Shah SP. Do fibers increase the tensile strength of cement-based matrix? Mater J. 1992;88:595–602.
  • Morsy MS, Alsayed SH, Aqel M. Effect of elevated temperature on mechanical properties and microstructure of silica flour concrete. Int J Civ. Environ Eng. 2010;10:1–6.
  • Anand N, Arulraj G, Aravindhan C. Stress strain behavior of Normal compacting and Self compacting concrete under elevated temperatures. J Struct Fire Eng. 2014;5:63–75.
  • Godwin A, Anand N, Prince Arulraj G. Influence of mineral admixtures on mechanical properties of self-compacting concrete under elevated temperature. Fire Mater. 2016;40:940–958.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.