[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/cac.2022.29.5.303

Thickness of shear flow path in RC beams at maximum torsional strength

Kim, Hyeong-Gook (Department of Architectural and Urban System Engineering, Kongju National University)
Lee, Jung-Yoon (School of Civil and Architectural Engineering, Sungkyunkwan University)
Kim, Kil-Hee (Department of Architectural and Urban System Engineering, Kongju National University)

Publication Information

Computers and Concrete / v.29, no.5, 2022 , pp. 303-321 More about this Journal

Abstract

The current design equations for predicting the torsional capacity of RC members underestimate the torsional strength of under-reinforced members and overestimate the torsional strength of over-reinforced members. This is because the design equations consider only the yield strength of torsional reinforcement and the cross-sectional properties of members in determining the torsional capacity. This paper presents an analytical model to predict the thickness of shear flow path in RC beams subjected to pure torsion. The analytical model assumes that torsional reinforcement resists torsional moment with a sufficient deformation capacity until concrete fails by crushing. The ACI 318 code is modified by applying analytical results from the proposed model such as the average stress of torsional reinforcement and the effective gross area enclosed by the shear flow path. Comparison of the calculated and observed torsional strengths of existing 129 test beams showed good agreement. Two design variables related to the compressive strength of concrete in the proposed model are approximated for design application. The accuracy of the ACI 318 code for the over-reinforced test beams improved somewhat with the use of the approximations for the average stresses of reinforcements and the effective gross area enclosed by the shear flow path.

Keywords

average stress; cracked concrete; shear flow path; torsional reinforcement; torsional strength;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	Kim, C., Kim, S., Kim, K.H., Shin, D., Haroon, M. and Lee, J.Y. (2019), "Torsional behavior of reinforced concrete beams with high-strength steel bars", ACI Struct. J., 116(6), 251-263.
2	Hsu, T.T.C. (1990), "Shear flow zone in torsion of reinforced concrete", J. Struct. Eng. ASCE, 116(11), 3206-3226. DOI
3	Bernardo, L.F.A., Andrade, J.M.A. and Lopes, S.M.R. (2012), "Softened truss model for reinforced NSC and HSC beams under torsion: A comparative study", Eng. Struct., 42, 278-296. https://doi.org/10.1016/j.engstruct.2012.04.036. DOI
4	Chen, S. and Kabeyasawa, T. (2004), "Average stress-strain relationship of steel bars embedded in concrete", Proceeding of the 13th World Conference on Earthquake Engineering, Vancouver, August.
5	Comite Euro-International du Beton (CEB) (1990), CEB-FIP model code 1990, Comite Euro-International du Beton (CEB), London, UK.
6	CSA Committee A23.3:19 (2019), Design of Concrete Structures, Canadian Standards Association, Toronto, ON, Canada.
7	El-Degwy, W.M. and McMullen, A.E. (1985), "Prestressed concrete tests compared with torsion theories", PCI J., 30(5), 96-127. DOI
8	Jeong, Y.S., Kwon, M.H. and Kim, J.S. (2021), "Development of a lattice model for predicting nonlinear torsional behavior of RC beams", Struct. Eng. Mech., 79(6), 779-789. https://doi.org/10.12989/sem.2021.79.6.779. DOI
9	Fang, I.K. and Shiau, J.K. (2004), "Torsional behavior of normal-and high-strength concrete beams", ACI Struct. J., 101(3), 304-313.
10	Hsu, T.T.C. (1988), "Softened truss model theory for shear and torsion", ACI Struct. J., 85(6), 624-635.
11	Kanakubo, T. and Hosoya, H. (2015), "Bond splitting strength of reinforced strain-hardening cement composite elements with small bar spacing", ACI Struct. J., 112(17), 189-198.
12	JSCE Guidelines for Concrete (2007), Standard Specifications for Concrete Structures, Japan Society of Civil Engineering, Tokyo, Japan.
13	EC2 (2005), Eurocode 2: Design of Concrete Structures-Part 1-1: General Rules and Rules for Buildings, European Committee for Standardization (CEN), Brussels, Belgium.
14	ACI Committee (2019), Building Code Requirements for Structural Concrete (ACI 318-19) and Commentary, American Concrete Institute, Farmington Hills, USA.
15	Adebar, P. (1989), "Shear design of concrete offshore structures", Ph.D. Dissertation of Philosophy, University of Toronto, Toronto.
16	Belarbi, A. and Hsu, T.T.C. (1994), "Constitutive laws of concrete in tension and reinforcing bars stiffened by concrete", ACI Struct. J., 91(4), 465-474.
17	Bernardo, L.F.A. and Lopes, S.M.R. (2009), "Torsion in HSC hollow beams: strength and ductility analysis", ACI Struct. J., 106(1), 39-48.
18	Hsu, T.T.C. (1968), "Torsion of structural concrete-Behavior of reinforced concrete rectangular members", Torsion of structural concrete, SP18, American Concrete Institute, Detroit, 261-306.
19	Ibraheem, O.F. and Mukhlif, O.A. (2021), "Torsional behavior of reinforced concrete plates under pure torsion", Comput. Concrete, 28(3), 311-319. https://doi.org/10.12989/cac.2021.28.3.311. DOI
20	Ju, H.J., Han, S.J., Kim, K.S., Strauss, A. and Wu, W. (2020), "Multi-potential capacity for reinforced concrete members under pure torsion", Struct. Eng. Mech., 75(3), 401-414. https://doi.org/10.12989/sem.2020.75.3.401. DOI
21	Kanakubo, T., Yonemaru, K. and Fukuyama, H. (1997), "Study on bond splitting behavior of reinforced concrete members: Part 1 - Local bond stress and slippage without lateral reinforcement", J. Struct. Constr. Eng., 492, 99-106.
22	Kim, M.J., Kim, H.G., Lee, Y.J., Kim, D.H., Lee, J.Y. and Kim, K.H. (2020), "Pure torsional behavior of RC beams in relation to the amount of torsional reinforcement and cross-sectional properties", Const. Build. Mater., 260(10), 1-17. https://doi.org/10.1016/j.conbuildmat.2020.119801. DOI
23	Kuan, A., Bruun, E.P.G, Bentz, E.C. and Collins, M.P. (2019), "Nonlinear sectional analysis of reinforced concrete beams and shells subjected to pure torsion", Comput. Struct., 222, 118-132. https://doi.org/10.1016/j.compstruc.2019.07.001. DOI
24	Peng, X.N. and Wong, Y.L. (2011), "Behavior of reinforced concrete walls subjected to monotonic pure torsion-An experimental study", Eng. Struct., 33, 4295-2508. https://doi.org/10.1016/j.engstruct.2011.04.022. DOI
25	Kim, S.W., Kim, Y.S., Kim, M.J., Lee, J.S. and Kim, K.H. (2014), "Evaluation of bond performance of RC beams with U-shaped reinforcement", Struct. Eng. Int., 124(3), 330-340. https://doi.org/10.2749/101686614X13830788506440. DOI
26	Lee, J.Y. and Kim, U.Y (2008), "Effect of longitudinal tensile reinforcement ratio and shear span-to-depth ratio on minimum shear reinforcement in beams", ACI Struct. J., 105(2), 134-144.
27	McMullen, A.E. and Rangan, V. (1978). "Pure torsion in rectangular sections-A re-examination", ACI Struct. J. Proc., 75(10), 511-519.
28	Maekawa, K., Pimanmas, A. and Okamura, H. (2003), Nonlinear Mechanics of Reinforced Concrete, CRC Press.
29	Mitchell, D. and Collins, M.P. (1974), "Behavior of structural concrete beams in pure torsion", Department of Civil Engineering, University of Toronto, Publication No. 74-06, 88.
30	Rahal, K.N. (2021), "A unified approach to shear and torsion in reinforced concrete", Struct. Eng. Mech., 77(5), 691-703. https://doi.org/10.12989/sem.2021.77.5.691. DOI
31	Rahal, K.N. and Collins, M.P. (1995), "Analysis of sections subjected to combined shear and torsion-A theoretical model", ACI Struct. J., 92(4), 459-469.
32	Rahal, K.N. and Collins, M.P. (1996), "Simple model for predicting torsional strength of reinforced and prestressed concrete sections", ACI Struct. J., 93(6), 658-666.
33	Sato, Y., Nagatomo, K. and Nakamura, Y. (2003), "Bond-strengthening hooks for RC members with 1300 MPa-class shear-reinforcing spirals", J. Asian Archit. Build. Eng., 2(2), 7-14.
34	Shima, H., Chou, L.L. and Okamura, H. (1987), "Micro and macro models for bond in reinforced concrete", J. Faculty Eng., 39(2), 133-194.
35	Tepfers, R. (1982), "Lapped tensile reinforcement splices", ASCE J. Struct. Div., 108(1), 283-301. DOI
36	Lee, J.Y. and Kim, S.W. (2010), "Torsional strength of RC beams considering tension stiffening effect", J. Struct. Eng., 136(11), 1367-1378. DOI
37	Choi, J.K. and Lee, S.C. (2019), "Sectional analysis procedure for reinforced concrete members subjected to pure torsion", Adv. Civ. Eng., 6019321. https://doi.org/10.1155/2019/6019321. DOI
38	Bernardo, L.F.A. (2019), "Generalized softened variable angle truss model", Mater., 12(13), 1-24. https://doi.org/10.1186/s40069-018-0285-0. DOI
39	Vecchio, F.J. and Collins, M.P. (1986), "The modified compression-field theory for reinforced concrete elements subjected to shear", ACI Struct. J., 83(2), 219-231.
40	Lee, J.Y., Kim, K.H., Lee, S.H., Kim, C.H. and Kim, M.H. (2018), "Maximum torsional reinforcement of reinforced concrete beams subjected to pure torsion", ACI Struct. J., 115(3), 749-760.