Advanced Theory of Concrete Structures Chapter 5 Shearing Behavior of Reinforced Concrete Structural Members Yong Zhou College of Civil Engineering,Tongji University 目 土本工程学院 yongzhou@tongji.edu.cn COLLEGEOF CNVIL INGINELRIM
Yong Zhou College of Civil Engineering, Tongji University yongzhou@tongji.edu.cn Chapter 5 Shearing Behavior of Reinforced Concrete Structural Members Advanced Theory of Concrete Structures
Introduction Concrete is quite strong in shear.Therefore shear by itself does not create any serious problems in RC members.However principle tensile stresses caused by shear combined with other stresses create a serious problem since the tensile strength of concrete is very low.Shear Failure t(max 90 4 目土本工程幸院
2 Introduction Concrete is quite strong in shear. Therefore shear by itself does not create any serious problems in RC members. However principle tensile stresses caused by shear combined with other stresses create a serious problem since the tensile strength of concrete is very low. ( Shear Failure ) 45o t(max) f = t f 90o s s s t f t f s
Introduction Characteristics of shear failure Abrupt without sufficient warning. Damage in shear tends to be more localized than in bending, i.e.,width of crack in shear is wider than in bending The nature of shear failure is very brittle.So it can result in catastrophic disaster if it is not properly designed. 土本工程学脱
3 Introduction ◼ Characteristics of shear failure ◼Abrupt without sufficient warning. ◼Damage in shear tends to be more localized than in bending, i.e., width of crack in shear is wider than in bending. ◼The nature of shear failure is very brittle. So it can result in catastrophic disaster if it is not properly designed
Shear Stress in an Uncracked Elastic Beam NMINIHIMINMMNIMIRmMMMNII R T-Sodd-fMdM Shear forces dT dMo T+dT-T=bvdx bl dT dMo Vo 1y= Section Beam Flexural Shear Shear dx dxbI bI element stresses flow stresses 目 土本工程学院
4 Shear Stress in an Uncracked Elastic Beam d d d My T A A I M MQ y A I I dMQ dT I = = = = = dT dM Q VQ v dx dxbI bI = = = T dT T bvdx + − =
Stress State in an Uncracked Elastic Beam ax (a) Shear stress,v Plane y Coordinates(0,v) Maximum shear stress, 45 Normal stress,f 28 Plane x Principal compressive Coordinates (f,v) stress,fe(max) Principal tensile stress, t(max) (b) 土本工程学院
5 Stress State in an Uncracked Elastic Beam
Stress State in an Uncracked Elastic Beam V N.A (c) Shear stress,v Plane y- Coordinates(0,v) 45 Maximum shear stress, Vma× 个120 0 Normal stress,f Plane x Coordinates (f v) IPrincipal compressive Principal tensile stress, stress,fc(max) ft(max) (d) 目 土本工程学院
6 Stress State in an Uncracked Elastic Beam
Principal Stresses 中A2 N.A. 中A, a Neutral axis Cross section Shear stress distribution or c(max) +v2 and tan20=2v 土本又程学院
7 Principal Stresses 2 2 or (max) 2 and tan 2 2 2 t t t c t f f v f v f = + =
Trajectory of principal stresses in an Uncracked Elastic Beam Crack type: Vertical cracks Diagonal cracks 闺土本红程幸悦
8 Trajectory of principal stresses in an Uncracked Elastic Beam Crack type: Vertical cracks Diagonal cracks
Shear Stress in an Cracked RC Beam Cracked Beam section Flexural stresses Shear flow Shear stresses Fig.7.3.Shear stresses across an idealized cracked reinforced concrete section. 1 dr 1d(M/jd)dm 1 V V= b。db。 dx dx bjd bjd V ACI:v= bd 土水工程学院
9 Shear Stress in an Cracked RC Beam 1 1 1 ( / ) w w w w dT dM V d M jd v b dx b dx dx b jd b jd = = = = ACI: w V v b d =
Formation of Diagonal cracks Flexure-shear diagonal crack Web-shear diagonal crack Diagonal cracking load Load by principal stress Shrinkage stresses,local weakening of a cross section by transverse reinforcement,redistribution of shear stresses between flexural cracks 土本工程学院
10 Formation of Diagonal cracks Flexure-shear diagonal crack Web-shear diagonal crack Diagonal cracking load ? Load by principal stress Shrinkage stresses, local weakening of a cross section by transverse reinforcement, redistribution of shear stresses between flexural cracks