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Innovative Infrastructure Solutions

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01.06.2021 | Review

CFRP for strengthening and repairing reinforced concrete: a review

verfasst von: Waseem Khairi Mosleh Frhaan, B. H. Abu Bakar, Nahla Hilal, Abdulkader Ismail Al-Hadithi

Erschienen in: Innovative Infrastructure Solutions | Ausgabe 2/2021

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Abstract

Carbon fibre-reinforced polymer (CFRP) is an emerging reinforcement in concrete materials and possesses many attractive mechanical and physical characteristics. Amongst other mechanical properties, CFRP has good compressive, flexural and shear strengths, and its usage improved ductility and suitability for preventing cracks. Thus, the application of CFRP is increasing in the construction industry. This review work highlights the effect of CFRP reinforcement on mechanical properties of reinforced concrete (RC) and self-compacting concrete (SCC) members. The scope of this review work is to highlight the effect on strengthening and repairing of RC members and SCC reinforced with CFRP material. A variety of research work has been reviewed on the use of CFRP in RC members, but the data remain limited yet. Thus, the critical review has been conducted from last 2-decades research on CFRP reinforcement in RC and SCC, and almost 60 researches and review articles have been involved in this discussion. The reviewed articles indicated that CFRP reinforcement can be suitable for the strength enhancement of RC members considering the strength-to-weight ratio despite its failure to produce more strength than steel reinforcement. Furthermore, CFRP is a good choice for repairing RC members due to its easy installation and other characteristic values. Therefore, CFRP reinforcement, which offers resistance to cracking, corrosion and temperature, is the best choice for concrete production.

Vorheriger Artikel Force-based finite element formulation for nonlinear behaviour of reinforced concrete frames

Nächster Artikel Development of supplementary cementitious materials from Algerian kaolin: elaboration of metakaolin and assessment of pozzolanicity

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Huang Y, Wu J, Yen T, Hung C, Lin Y (2005) Strengthening reinforced concrete beams using prestressed glass fiber-reinforced polymer—part I: experimental study. J Zhejian Univ Sci 6(3):166–174

Lamanna AJ (2002) Flexural strengthening of reinforced concrete beam with mechanically fastened fiber reinforced polymer strips. Ph.D. Thesis, University of Wisconsin-Madison, 287, p 8

Teng JG, Lam L, Chan W, Wang J (2000) Retrofitting of deficient RC cantilever slab using GFRP strips. J Compos Constr 4(2):75–84

Mstthys S, Tearwe L (2000) Concrete slab reinforced with FRP ׀׀: punching resistant. J Compos Constr 4(3):154–161

Wong RS (2001) Towards modelling of reinforced concrete members with externally-bonded fiber reinforced polymer (FRP) composites. M.Sc. Thesis, University of Toronto, 320

Ahmad S, Umar A (2018) Fiber-reinforced self-compacting concrete: a review. IOP Conf Ser Mater Sci Eng 377:012117

Hamakareem MI (2020) Fiber reinforced polymer (FRP) in construction, types, and uses. https://theconstructor.org/concrete/fibre-reinforced-polymer/1583/. Accessed 20 May 2020

Masuelli MA (2013) Introduction of fibre-reinforced polymers-polymers and composites: concepts, properties, and processes. INTECH Open Access Publisher, Rijeka

Bhatt P, Goe A (2017) Carbon fibres: production, properties, and potential use. Mater Sci Res India 14(1):52–57

10.

Yue L, Zwingmann B, Schlaich M (2015) Carbon fiber reinforced polymer for cable structures—a review. Polymers 7:2078–2099

11.

Sarker P, Begum M, Nasrin S (2011) Fiber-reinforced polymers for structural retrofitting: a review. J Civ Eng (IEB) 39(1):49–57

12.

Saim Raza S, Khan MKI, Menegon SJ, Tsang H-H, John Wilson JL (2019) Strengthening and repair of reinforced concrete columns by jacketing: state-of-the-art review. Sustainability 11:3208

13.

Alkhrdaji T (2015) Strengthening of concrete structures using FRP composites. In: Articles, building blocks. https://www.structuremag.org/?p=8643 (Cite on 24 May 2020)

14.

Mara V (2014) Fibre reinforced polymer bridge decks: sustainability and a novel panel-level connection. Licentiate Thesis, Chalmers University of Technology, Department of Civil and Environmental Engineering

15.

Jonas BVH (2018) Dynamic and economic aspects of carbon fiber reinforced polymer footbridges. Master’s Thesis, Chalmers University of Technology, Gothenburg, Sweden

16.

Grantan Design Limited, 2014 and 2015. CES EduPack Software

17.

Shuaib NA, Mativenga PT (2017) Carbon footprint analysis of fiber reinforced composite recycling process. Proceedia Manuf 7:183–190

18.

Osman BH, Wu E, Ji B et al (2017) Repair of pre-cracked reinforced concrete (RC) beams with openings strengthened using FRP sheets under sustained load. Int J Concr Struct Mater 11:171–183

19.

Panjehpour M, Farzadnia N, Anwar MP, Abang Ali AA (2011) FRP sheets contribution in common repair techniques of concrete structures with emphasis on concrete columns. Int J of Sustain Constr Eng Technol 2(2):54–61

20.

Jumaat MZ, Rahman MA, Alam MA, Rahman MM (2011) Premature failures in plate bonded strengthened RC beams with an emphasis on premature shear: a review. Int J Phys Sci 6(2):156–168

21.

Jumaat MZ, Alam MA (2008) Strengthening of R.C. beams using externally bonded plates and anchorages. Aust J Basic Appl Sci 3(3):2207–2211

22.

Al-Mahaidi R, Kalfat R (2018) Rehabilitation of concrete structures with fiber-reinforced polymer. Butterworth-Heinemann, Oxford

23.

FIB Bulletin 14 (2001) Externally bonded FRP reinforcement for RC structures. Task group 9.3, International Federation of Structural Concrete (FIB)

24.

Khalifa A, Alkhrdaji T, Nanni A, Lansburg S (1999) Anchorage of surface mounted FRP reinforcement. Concr Int Des Constr 21(10):49–50

25.

Grace NF, Abdel-Sayed G, Ragheb WF (2002) Strengthening of concrete beams using innovative ductile fiber-reinforced polymer fabric. ACI Struct J 99(5):692–700

26.

Alagusundaramoorthy P, Harik IE, Choo CC (2003) Flexural behavior of RC beams strengthened with carbon fiber reinforced polymer sheets or fabric. J Compos Constr. https://doi.org/10.1061/(ASCE)1090-0268(2003)7:4(292)CrossRef

27.

Adhikary BB, Mutsuyashi H, Ashraf M (2004) Shear strengthening of reinforced concrete beams using fiber-reinforced polymer sheets with bonded anchorage. ACI Struct J 101(5):660–668

28.

Adhikary BB, ASCE M, Musuyoshi H (2004) The behavior of concrete beams strengthened in shear with carbon-fiber sheets. J Compos Constr 8(3):258–264

29.

Al-Amery R, Al-Mahaidi R (2006) Coupled flexural-shear retrofitting of RC beams using CFRP straps. In: 13th international conference of composite structures, Melbourne, Australia. Composite structures 75, pp 457–464

30.

Jumatt MZ, Alam A (2008) Experimental and analytical investigation on the structural behaviour of steel plate and CFRP laminate flexurally strengthened concrete beams. J Appl Sci 8(23):4383–4389

31.

Jayaprakash J, Samad AA, Ashrabov AA, Chong KK (2008) Experimental investigation on shear resistance behaviour of RC precracked and non-precracked T-beams using discrete CFRP strips. Int J Integr Eng (Issue Civ Environ Eng), pp 1–15

32.

Ibrahim AM, Mohammed Sh, Mahmood S (2009) Finite element modeling of reinforced concrete beams strengthened with FRP laminates. Eur J Sci Res 30:526–541

33.

Siddiqui NA (2009) Experimental investigation of RC beams strengthened with externally bonded FRP composites. Latin Am J Solid Struct 6:343–362

34.

Bukhari AI, Vollum LR, Ahmad S, Sagaseta J (2010) Shear strengthening of reinforced concrete beams with CFRP. Mag Concr Res 62(1):65–77

35.

Enochsson O, Lundqvist J, Taljsten B, Rusinowski P, Olofsson T (2007) CFRP strengthened openings in two-way concrete slabs—an experimental and numerical study. Constr Build Mater 21:810–826

36.

Petrou M, Parler D, Harries K, Rizos D (2008) Strengthening of reinforced concrete bridge decks using carbon fiber-reinforced polymer composite materials. J Bridge Eng 13(5):455–467

37.

Maaddawy T, Soudki K (2008) Strengthening of reinforced concrete slabs with mechanically-anchored unbonded FRP system. Constr Build Mater 22:444–455

38.

Elsayed W, Ebead U, Neale K (2009) Mechanically fastened FRP-strengthened two-way concrete slabs with and without cutouts. J Compos Constr 13(3):198–207

39.

Hussein M, Fawzy T (2010) Structural performance of CFRP-strengthened RC slabs in a corrosive environment. J Compos Constr 14(6):865–869

40.

Seliem HM, Sumner EA, Seracino R, Smith ST (2011) Case study on the restoration of flexural capacity of continuous one-way RC slabs with cutouts. J Compos Constr 15(6):992–998

41.

Muhammed JA (2012) Experimental study of self compacting RC slabs with opening strengthening with carbon fiber laminated and steel fiber. J Eng Dev 16(1):54–74

42.

Heniegal AM (2012) Strengthening and repair of self compacting concrete beams. Mansoura Eng J 37(2):28–49

43.

Kadhim MMA (2013) Strengthening of full-scale RC one-way slab with cutouts. J Babylon Univ Eng Sci 21(2):570–581

44.

Salman WD (2013) Strengthening of reinforced concrete one-way slabs with opening using CFRP strip in flexural. Int J Sci Res (IJSR) 4(5):980–991

45.

Qian K, Li B (2013) Strengthening and retrofitting of RC flat slabs to mitigate progressive collapse by externally bonded CFRP laminates. J Compos Constr 17(4):554–565

46.

Florut SC, Gabriel S, Popescu C, Valeriu S (2014) Tests on reinforced concrete slabs with cut-out openings strengthened with fiber-reinforced polymers. Compos Part B 66:484–493

47.

Yu T, Fang XL, Teng JG, Asce M (2014) FRP-confined self-compacting concrete under axial compression. J Mater Civ Eng 26(11):04014082

48.

Önal MM (2014) Strengthening reinforced concrete beams with CFRP and GFRP. Adv Mater Sci Eng. https://doi.org/10.1155/2014/967964CrossRef

49.

Salman WD, Murtada AI, Qusay WA (2015) Strengthening of reinforced concrete one-way slabs using CFRP in flexural. J Eng Sci Res Technol 4(8):2277–9655

50.

Jamal AK, Atea RS (2015) Flexural behavior of self-compacting concrete beams strengthened with carbon fiber reinforced polymer sheets. Int J Adv Res 3(1):714–722

51.

Al-Rousan R, Haddad R, Al-Halboni A (2015) Bond–slip behavior between self-compacting concrete and carbon-fiber-reinforced polymer sheets. Mag Concr Res 67(2):89–103

52.

Yakhlaf M, Soudki KA (2015) Carbon fiber reinforced self-consolidating concrete—fresh and mechanical properties. ACI Symp Publ 299:1–16

53.

Güneyisi E, Gesoğlu M, Mustafa FH, İpek S (2015) Mechanical and fracture properties of carbon fiber reinforced self-compacting concrete composites. In: 10th International conference on composite science and technology At: Av. Rovisco Pais 1049-001 Lisboa Portugal

54.

Mastali M, Dalvand A (2016) The impact resistance and mechanical properties of self-compacting concrete reinforced with recycled CFRP pieces. Compos B Eng 92(1):360–376

55.

Hamdy KS, Eisa AS, El-Awady KA (2017) Strengthening of cutouts in existing one-way spanning R.C. flat slabs using CFRP sheets. J Concr Struct Mater 4:976-0485

56.

Cholker AK, Tantray MA (2019) Mechanical and durability properties of self-compacting concrete reinforced with carbon fibers. Int J Recent Technol Eng 7(6):1738–1743

57.

Ashteyata AM, Haddadb R, Yasmeen TO (2020) Repair of heat-damaged SCC cantilever beams using SNSM CFRP strips. Struct Mater 24:151–162

58.

Jonbi ARN, Permatasari M, Partogi HS (2020) Comparative of the use of carbon and steel fiber to the mechanical properties of self compacting concrete. Solid State Phenomena 304:75–80

Titel: CFRP for strengthening and repairing reinforced concrete: a review
verfasst von: Waseem Khairi Mosleh Frhaan
B. H. Abu Bakar
Nahla Hilal
Abdulkader Ismail Al-Hadithi
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/s41062-020-00417-5

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