Innovative hybrid reinforcement constituting conventional longitudinal steel and FRP stirrups for improved seismic strength and ductility of RC structures

Mostafa FAKHARIFAR; Ahmad DALVAND; Mohammad K. SHARBATDAR; Genda CHEN; Lesley SNEED

doi:10.1007/s11709-015-0295-9

Front. Struct. Civ. Eng. ›› 2016, Vol. 10 ›› Issue (1) : 44 -62. DOI: 10.1007/s11709-015-0295-9

RESEARCH ARTICLE

Innovative hybrid reinforcement constituting conventional longitudinal steel and FRP stirrups for improved seismic strength and ductility of RC structures

Author information +

History +

PDF (3995KB)

Abstract

The use of fiber reinforced polymer (FRP) reinforcement is becoming increasingly attractive in construction of new structures. However, the inherent linear elastic behavior of FRP materials up to rupture is considered as a major drawback under seismic attacks when significant material inelasticity is required to dissipate the input energy through hysteretic cycles. Besides, cost considerations, including FRP material and construction of pre-fabricated FRP configurations, especially for stirrups, and probable damage to epoxy coated fibers when transported to the field are noticeable issues. The current research has proposed a novel economical hybrid reinforcement scheme for the next generation of infrastructures implementing on-site fabricated FRP stirrups comprised of FRP sheets. The hybrid reinforcement consists of conventional longitudinal steel reinforcement and FRP stirrups. The key feature of the proposed hybrid reinforcement is the enhanced strength and ductility owing to the considerable confining pressure provided by the FRP stirrups to the longitudinal steel reinforcement and core concrete. Reinforced concrete beam specimens and beam-column joint specimens were tested implementing the proposed hybrid reinforcement. The proposed hybrid reinforcement, when compared with conventional steel stirrups, is found to have higher strength, stiffness, and energy dissipation. Design methods, structural behavior, and applicability of the proposed hybrid reinforcement are discussed in detail in this paper.

Graphical abstract

Keywords

FRP / ductility / confinement / seismic / shear

Cite this article

Download citation ▾

Mostafa FAKHARIFAR, Ahmad DALVAND, Mohammad K. SHARBATDAR, Genda CHEN, Lesley SNEED. Innovative hybrid reinforcement constituting conventional longitudinal steel and FRP stirrups for improved seismic strength and ductility of RC structures. Front. Struct. Civ. Eng., 2016, 10(1): 44-62 DOI:10.1007/s11709-015-0295-9

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Koch G H, Brongers M P, Thompson N G, Virmani Y P, Payer J H. Corrosion costs and preventive strategies in the United States. Washington DC: FHWA, 2001

[2]	You Y M, Sneed L H, Belarbi A. Numerical simulation of partial-depth precast concrete bridge deck spalling. Journal of Bridge Engineering, 2011, 17(3): 528–536

[3]	Fukuyama H, Masuda Y, Sonobe Y, Tanigaki M. (33 Structural Performances of Concrete Frame Reinforced with FPR Reinforcement. In Non-Metallic (FRP) Reinforcement for Concrete Structures: Proceedings of the Second International RILEM Symposium. CRC Press, 1995, 29: 275

[4]	American Concrete Institute (ACI). Guide for the design and construction of concrete reinforced with FRP bars.” ACI 440.1R–06, Farmington Hills, MI, 2006

[5]	American Concrete Institute (ACI). Guide for the design and construction of externally bonded FRP systems for strengthening concrete structures. ACI 440.2R–02, Farmington Hills, MI, 2002

[6]	CSA. Design and Construction of Building Components with Fiber-Reinforced Polymers. CSA S806–02, Canadian Standards Association, Rexdale, Ont., Canada, 2002

[7]	Japan Society of Civil Engineers (JSCE). Recommendation for Design and Construction of Concrete Structures Using Continuous Fiber Reinforcing Materials. Concrete Engineering Series 23, Tokyo: Japan Society of Civil Engineers, 1997

[8]	Nanni A. North American design guidelines for concrete reinforcement and strengthening using FRP: principles, applications and unresolved issues. Construction & Building Materials, 2003, 17(6): 439–446

[9]	Bank L C. Composites for Construction: Structural Design with FRP Materials. John Wiley and Sons, 2006

[10]	He R, Sneed L H, Belarbi A. Rapid repair of severely damaged RC columns with different damage conditions: An experimental study. International Journal of Concrete Structures and Materials, 2013, 7(1): 35–50

[11]	ElGawady M, Endeshaw M, McLean D, Sack R. Retrofitting of rectangular columns with deficient lap splices. Journal of Composites for Construction, 2009, 14(1): 22–35

[12]	Fakharifar M, Sharbatdar M K, Lin Z. Seismic Performance and Global Ductility of Reinforced Concrete Frames with CFRP Laminates Retrofitted Joints. In Structures Congress 2013@ sBridging Your Passion with Your Profession. ASCE, 2080–2093

[13]	Lau K, Zhou L. Mechanical performance of composite-strengthened concrete structures. Composites. Part B, Engineering, 2001, 32(1): 21–31

[14]	Fakharifar M, Sharbatdar M K, Lin Z, Dalvand A, Sivandi-Pour A, Chen G. Seismic performance and global ductility of RC frames rehabilitated with retrofitted joints by CFRP laminates. Earthquake Engineering and Engineering Vibration, 2014, 13(1): 59–73

[15]	Fakharifar M, Lin Z B, Wu C L, Mahadik-Khanolkar S, Leventis N, Chen G D. Microstructural characteristics of polyurea and polyurethanexerogels for concrete confinement with FRP system. Advanced Materials Research, 2013, 742: 237–242

[16]	Fakharifar M, Chen G, Lin Z, Woolsey Z. Behavior and strength of passively confined concrete filled tubes. In: Proceedings of the 10th U S National Conference on Earthquake Engineering. Anchorage, Alaska, 2014-July-21

[17]	De Lorenzis L, Nanni A. Bond between near-surface mounted fiber-reinforced polymer rods and concrete in structural strengthening. ACI Structural Journal, 2002, 99(2)

[18]	De Lorenzis L, Nanni A. Shear strengthening of reinforced concrete beams with near-surface mounted fiber-reinforced polymer rods. ACI Structural Journal, 2001, 98(1)

[19]	Jalali M, Sharbatdar M K, Chen J F, Jandaghi Alaee F. Shear strengthening of RC beams using innovative manually made NSM FRP bars. Construction & Building Materials, 2012, 36: 990–1000

[20]	Breveglieri M, Barros J A, Dalfré G M, Aprile A. A parametric study on the effectiveness of the NSM technique for the flexural strengthening of continuous RC slabs. Composites. Part B, Engineering, 2012, 43(4): 1970–1987

[21]	Capozucca R. Static and dynamic response of damaged RC beams strengthened with NSM CFRP rods. Composite Structures, 2009, 91(3): 237–248

[22]	Barris C, Torres L, Turon A, Baena M, Catalan A. An experimental study of the flexural behaviour of GFRP RC beams and comparison with prediction models. Composite Structures, 2009, 91(3): 286–295

[23]	Capozucca R. Analysis of the experimental flexural behaviour of a concrete beam grid reinforced with C-FRP bars. Composite Structures, 2007, 79(4): 517–526

[24]	Rafi M M, Nadjai A, Ali F, Talamona D. Aspects of behaviour of CFRP reinforced concrete beams in bending. Construction & Building Materials, 2008, 22(3): 277–285

[25]	Bentz E C, Massam L, Collins M P. Shear strength of large concrete members with FRP reinforcement. Journal of Composites for Construction, 2010, 14(6): 637–646

[26]	Eitel A K. Performance of a GFRP Reinforced Concrete Bridge Deck. Dissertation for the Doctoral Degree. Cleveland, Ohio, USA: Case Western Reserve University, 2005

[27]	Lin Z, Fakhairfar M, Wu C, Chen G, Bevans W, Gunasekaran A V K, Sedighsarvestani S. Design, Construction and Load Testing of the Pat Daly Road Bridge in Washington County, MO, with Internal Glass Fiber Reinforced Polymers Reinforcement (No. NUTC R275), 2013

[28]	Sharbatdar M K, Saatcioglu M, Benmokrane B. Seismic flexural behavior of concrete connections reinforced with CFRP bars and grids. Composite Structures, 2011, 93(10): 2439–2449

[29]	Nanni A. Flexural behavior and design of RC members using FRP reinforcement. Journal of Structural Engineering, 1993, 119(11): 3344–3359

[30]	CSA. Canadian Standards Association. Fibre Reinforced Structures, Canadian Highway Bridge Design Code (CHBDC), Section 16, Standard CAN/CSA-S6–00 (Rexdale: Ont.: CSA International, 2000).

[31]	Tureyen A K, Frosch R J. Concrete shear strength: another perspective. ACI Structural Journal, 2003, 100(5): 609–615

[32]	American Concrete Institute ACI Committee. Building code requirements for structural concrete ACI 318-08 and commentary 318R-08. ACI 318–08/318R–08, Farmington Hills, MI: American Concrete Institute, 2008

[33]	Kim W, El-Attar A, White R N. Small-scale modeling techniques for reinforced concrete structures subjected to seismic loads, Report No. NCEER-88–0041, National Center for Earthquake Engineering Research, State University of New York at Buffalo, November; 1989