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01.06.2021 | Technical paper

Comprehensive study on performance of glass fibers-based concrete

verfasst von: Nerella Ruben, Chava Venkatesh, Chereddy Sonali Sri Durga, Madduru Sri Rama Chand

Erschienen in: Innovative Infrastructure Solutions | Ausgabe 2/2021

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Abstract

Concrete is a typical brittle material; it has poor ductility, low tensile strength, and prone to micro-cracks. To overcome this behavior, alkali-resistant glass fibers (AGF) are added to concrete in present study, and this is the principal route for usage of glass fibers in structural concrete from laboratory investigation to industrial usage. Here, alkali-resistant glass fibers are used as an additive to concrete with 1–3% of cement weight. Moreover, detailed investigations were conducted on workability (slump cone test), mechanical strength (split tensile, compressive, and flexural strength tests), durability studies [Rapid chloride permeability test (RCPT) and Accelerated corrosion test (ACT)] and microstructure analysis [Scanning electron microscopy (SEM) with Energy-dispersive X-ray spectroscopy analysis (EDS)]. Glass fibers additive mixes have shown a negative effect on fresh properties and positive impact on durability and mechanical properties with increased addition of it. Meanwhile, the microstructure analysis reported that bonding between cementitious matrix and glass fiber is adequate up to 2%. The addition of glass fibers enriched dense surface formation of concrete.

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Campello E, Pereira MV, Darwish F (2014) The effect of short metallic and polymeric fiber on the fracture behavior of cement mortar. Procedia Mater Sci 3:1914–1921

Venkatesh C, Nerella R, Chand MSR (2020) Experimental investigation of strength, durability, and microstructure of red-mud concrete. J Korean Ceram Soc 57:1–8

Dai J, Ueda T, Sato Y (2005) Development of the nonlinear bond stress–slip model of fiber reinforced plastics sheet–concrete interfaces with a simple method. J Compos Constr 9(1):52–62

Chandramouli K, Srinivasa RP, Pannirselvam N, Seshadri ST, Sravana P (2010) Strength properties of glass fiber concrete. ARPN J Eng Appl Sci 5(4):1–6

Ozerkan NG, Ahsan B, Mansour S, Iyengar SR (2013) Mechanical performance and durability of treated palm fiber reinforced mortars. Int J Sustain Built Environ 2(2):131–142

Simões T, Costa H, Dias-da-Costa D, Júlio E (2018) Influence of type and dosage of micro-fibres on the physical properties of fibre reinforced mortar matrixes. Constr Build Mater 187:1277–1285

Kakooei S, Akil HM, Jamshidi M, Rouhi J (2012) The effects of polypropylene fibers on the properties of reinforced concrete structures. Constr Build Mater 27(1):73–77

Iqbal S, Ali I, Room S, Khan SA, Ali A (2019) Enhanced mechanical properties of fiber reinforced concrete using closed steel fibers. Mater Struct 52(3):56

Algburi AH, Sheikh MN, Hadi MNS (2019) Mechanical properties of steel, glass, and hybrid fiber reinforced reactive powder concrete. Front Struct Civil Eng 13(4):998–1006

10.

Abukhashaba MI, Mostafa MA, Adam IA (2014) Behavior of self-compacting fiber reinforced concrete containing cement kiln dust. Alex Eng J 53(2):341–354

11.

Bendjillali K, Goual MS, Chemrouk M, Damene Z (2011) study of the reinforcement of limestone mortars by polypropylene fibers waste. Phys Procedia 21:42–46

12.

Qureshi LA, Sheikh MI, Sultan T (2013) Effect of mixing fiber cocktail on flexural strength of concrete. Procedia Eng 54:711–719

13.

Yang IH, Joh C, Kim BS (2011) Flexural strength of ultra high strength concrete beams reinforced with steel fibers. Procedia Eng 14:793–796

14.

Ezeldin AS, Balaguru PN (1992) Normal-and high-strength fiber-reinforced concrete under compression. J Mater Civ Eng 4(4):415–429

15.

Saidani M, Saraireh D, Gerges M (2016) Behaviour of different types of fibre reinforced concrete without admixture. Eng Struct 113:328–334

16.

Sofi A (2018) effect of waste tyre rubber on mechanical and durability properties of concrete—a review. Ain Shams Eng J 9(4):2691–2700

17.

Li G, Stubblefield MA, Garrick G, Eggers J, Abadie C, Huang B (2004) Development of waste tire modified concrete. Cem Concr Res 34(12):2283–2289

18.

Gupta T, Chaudhary S, Sharma RK (2014) Assessment of mechanical and durability properties of concrete containing waste rubber tire as fine aggregate. Constr Build Mater 73:562–574

19.

Liu J, Jia Y, Wang J (2019) Experimental study on mechanical and durability properties of glass and polypropylene fiber reinforced concrete. Fibers Polym 20(9):1900–1908

20.

Issa MA, Ovitigala T, Ibrahim M (2016) Shear behavior of basalt fiber reinforced concrete beams with and without basalt FRP stirrups. J Compos Constr 20(4):04015083

21.

Hilles MM, Ziara MM (2019) Mechanical behavior of high strength concrete reinforced with glass fiber. Eng Sci Technol Int J 22(3):920–928

22.

Ghorpade VG (2010) An experimental investigation on glass fibre reinforced high performance concrete with silica fume as admixture. In: 35th Conference on Our World in Concrete and Structures

23.

Swami BLP, Asthana AK, Masood U (2009) Studies on glass fiber reinforced concrete composites–strength and behavior. Challenges, opportunities and solutions in structural engineering and construction. CRC Press, Boca Raton, pp 623–626

24.

Ayub T, Shafiq N, Nuruddin MF (2014) Mechanical properties of high-performance concrete reinforced with basalt fibers. Procedia Eng 77:131–139

25.

Ali B, Qureshi LA (2019) Influence of glass fibers on mechanical and durability performance of concrete with recycled aggregates. Constr Build Mater 228:116783

26.

Durga CSS, Ruben N, Chand MSR, Venkatesh C (2019) Performance studies on rate of self healing in bio concrete. Mater Today Proc

27.

Durga CSS, Ruben N, Chand MSR, Venkatesh C (2019) Evaluation of mechanical parameters of bacterial concrete. Annales de Chimie-Science des Matériaux 43(6):395–399

28.

Durga CSS, Ruben N (2019) Assessment of various self healing materials to enhance the durability of concrete structures. Annales De Chimie-Science des Matériaux 43(2):75–79

29.

Durga CSS, Ruben N (2019) A review of the mechanical behavior of substitution materials in self-healing concrete. Sustainable construction and building materials. Springer, Singapore, pp 135–144

30.

BIS, IS 269 (2015) Specifications for 53 grade ordinary Portland cement. Bureau of Indian Standards, New Delhi

31.

BIS, IS 383–2016 (2016) Specification for coarse and fine aggregates from natural sources for concrete. Bureau of Indian Standards, New Delhi

32.

BIS, IS 10262–2019 (2019) Specification for mix design guidelines for concrete. Bureau of Indian Standards, New Delhi

33.

BIS, IS 1199–1959 (1959) Slump test of fresh concrete to measure workability. Bureau of Indian Standards, New Delhi

34.

BIS, IS: 516–2013 (2013) Specification for method of tests for concrete. Bureau of Indian Standards, New Delhi

35.

BIS, IS 5816–1999 (1999) Specification for splitting tensile strength of concrete—method of test. Bureau of Indian Standards, New Delhi

36.

BIS, IS 516–1959 (1959) Specification for flexural strength of concrete—method of test. Bureau of Indian Standards, New Delhi

37.

ASTM C1202–19 (2019) Standard test method for electrical indication of concrete’s ability to resist chloride ion penetration. ASTM, West Conshohocken

38.

ASTM G109–07 (2013) Standard test method for determining effects of chemical admixtures on corrosion of embedded steel reinforcement in concrete exposed to chloride environments. ASTM, West Conshohocken

39.

Venkatesh C, Ruben N, Chand MSR (2020) Red mud as an additive in concrete: comprehensive characterization. J Korean Ceram Soc. https://doi.org/10.1007/s43207-020-00030-3CrossRef

40.

Sahmaran M, Yurtseven A, Yaman IO (2005) workability of hybrid fiber reinforced self-compacting concrete. Build Environ 40(12):1672–1677

41.

Ding YN, Liu SG, Zhang YL, Thomas A (2008) The investigation on the workability of fibre cocktail reinforced self-compacting high performance concrete. Constr Build Mater 22(7):1462–1470

42.

Johnston CD (2014) Fiber-reinforced cements and concretes. CRC Press, Boca Ratob

43.

BIS, IS 1124–1974 (1974) Specification for water absorption for concrete. Bureau of Indian Standards, New Delhi

44.

Hannawi K, Bian H, Prince-Agbodjan W, Raghavan B (2016) Effect of different types of fibers on the microstructure and the mechanical behavior of ultra-high performance fiber-reinforced concretes. Compos B Eng 86:214–220

45.

Xue G, Yilmaz E, Song W, Cao S (2019) Mechanical, flexural and microstructural properties of cement-tailings matrix composites: effects of fiber type and dosage. Compos B Eng 172:131–142

46.

Yuan Z, Jia Y (2021) Mechanical properties and microstructure of glass fiber and polypropylene fiber reinforced concrete: an experimental study. Constr Build Mater 266:121048

47.

Bodur MS, Englund K, Bakkal M (2017) Water absorption behavior and kinetics of glass fiber/waste cotton fabric hybrid composites. J Appl Polym Sci 134(47):45506

48.

Rossignolo JA (2009) Interfacial interactions in concretes with silica fume and SBR latex. Constr Build Mater 23(2):817–821

49.

Sri Rama Chand M, Rathish Kumar P, Swamy Naga Ratna Giri P, Rajesh Kumar G (2018) Performance and microstructure characteristics of self-curing self-compacting concrete. Adv Cement Res 30(10):451–468

50.

Qing F, Beixing L, Jiangang Y, Xiaolu Y (2017) Microstructural and microanalytical study on concrete exposed to the sulfate environment. In: IOP Conference Series: Materials Science and Engineering, Vol. 269, no. 1, p. 012070. IOP Publishing

51.

BIS, IS:4031 (1996) Part 1: 1996-Method of physical test for cement (Determination of fineness by dry sieving. Bureau of Indian Standards, New Delhi

52.

BIS, IS 456269 (2000) Specifications for plain and reinforced concrete-code of practice. Bureau of Indian Standards, New Delhi

Titel: Comprehensive study on performance of glass fibers-based concrete
verfasst von: Nerella Ruben
Chava Venkatesh
Chereddy Sonali Sri Durga
Madduru Sri Rama Chand
Publikationsdatum: 01.06.2021
Verlag: Springer International Publishing
Erschienen in: Innovative Infrastructure Solutions / Ausgabe 2/2021
Print ISSN: 2364-4176
Elektronische ISSN: 2364-4184
DOI: https://doi.org/10.1007/s41062-021-00490-4

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