Corbel For Mac



Introduction

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Corbel is a short structural element that cantilevers out from column/wall to support load. Generally, the corbel is casted monolithically with column/wall.

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There are several typical modes of failure in the corbel. The most common of which are yielding of the tension tie, failure of the end anchorages of the tension tie, either under the load point or in the column, failure of the compression strut by crushing or shearing, and local failures under the bearing plate.

The following figures shows the failure mode of corbel

Design of Corbel

The corbel must be designed to resist simultaneously Vu, a factored moment Mu and a factored horizontal tensile force Nuc. ACI Code Section 11.8 requires corbels having a/d between 1 and 2 to designed using Appendix A, strut-and-tie models, where a is the distance from the load to the face of column and d is the depth of the corbel below the tie, measured at the face of the column. Corbels having a/d less than or equal 1 may be designed using either strut-and-tie models or traditional ACI designed method, Section 11.8. This paper presents Corbels design according to traditional ACI method.

ACI Design Method

Shear Design of Corbel

To avoid the crack that occurs in the interface of the corbel and the column we must provide the shear friction reinforcement perpendicular with the cracks direction. We use coefficient of friction μ to transform the horizontal resisting force into vertical resisting force.

The nominal shear strength of shear reinforcement can be determined using equations below

Vn = Avf fy μ for vertical shear friction reinforcement, and

Vn = Avf fysin αf + cos αf) for inclined shear reinforcement

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where

Vn : nominal shear strength of shear friction reinforcement

Avf : area of shear friction reinforcement

fy : yield strength of shear friction reinforcement

μ : coefficient of friction

MethodCoefficient of Friction, μ
Concrete cast monolithic1.4λ
Concrete placed against roughened hardened concrete1.0λ
Concrete placed against unroughened hardened concrete0.6λ
Concrete anchored to structural steel0.7λ

The value of λ is 1.0 for normal weight concrete, 0.85 for sand light weight concrete and 0.75 for all light weight concrete.

The maximum nominal shear force, Vn shall not exceed the smallest of 0.2 fc’ bw d and 5.5 bw d, where

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fc’ : compression strength of concrete (MPa)

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bw : width of corbel section (mm)

d : effective depth of corbel (mm)

Flexural Design of Corbel

The corbel is designed to resist ultimate flexural moment result from the supported beam reaction, Vu and horizontal force from creep and shrinkage, Nuc. The minimum value of Nuc is 0.2 Vu and not greater than Vu.

Tension Reinforcement

The ultimate horizontal force, Nuc shall be resisted by tension reinforcement as follow

An = Nuc / ϕfy

Where:

An : area of tension reinforcement

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Nuc : ultimate horizontal force at corbel

fy : yield strength of shear friction reinforcement

ϕ : strength reduction factor

Flexural Reinforcement

The ultimate flexure moment, Mu is

Mu = Vu av + Nuc (h – d)

Where:

Mu : ultimate flexure moment

Vu : ultimate shear force

av : distance from Vu to the face of column

Nuc : ultimate horizontal force at corbel

h : height of corbel

d : effective depth of corbel

Mu ≤ ϕ Af fy (d-a/2) where

a = Af fy / 0.85f’c b

From the equation above, area of flexural reinforcement, Afcan be determined using trial and error. As first trial, (d – a/2) can be assumed 0.9d so that

Af ≥ Mu / ϕ fy (0.9d)

For practical reason, the value of (d – a/2) can be used 0.85d

Af ≥ Mu / ϕ fy (0.85d)

After finding Avf, An, and Af, we must then calculate the primary tension reinforcement Asc from the larger of Af + An and 2Avf/3 + An

Reinforcement Limits

The primary steel reinforcement at corbel design,

Asc shall not be less than 0.04 fc‘ bw d /fy

The horizontal closed stirrups,

Ah shall not be less than 0.5 (Asc – An)

Distribution of Corbel Reinforcement

The horizontal closed stirrups, Ah shall be distributed uniformly within (2/3) d adjacent to primary tension reinforcement.

Design Procedure

Step 1. Find factored shear Vu and tensile force Nuc

If Nuc is not specified, use a minimum value of Nuc = 0.2 Vu(ACI 11.9.3.4)

Compute nominal values of shear and tensile force

Vn = Vu / 0.75 ; Nnc = Nuc / 0.75

If Vn > 0.2 fc’ b d OR

Vn > 5.5 b d then section size is inadequate (ACI 11.9.3.2)

Step 2. Compute shear-friction reinforcement (ACI 11.7.4.1)

Avf = Vn /μ fy

Step 3. Calculate required flexural reinforcement (11.9.3.3)

Mu = Vu av + Nuc (h – d)

Af = Mu / ϕ fy (jd) (assume jd = 0.85d)

Step 4. Reinforcement to carry tensile force (ACI 11.9.3.4)

An = Nuc / ϕfy

Step 5. Required main flexural steel (Asc) is given by (ACI 11.9.3.5 and 11.9.5)

the larger of

Af + An and 2Avf/3 + An

Step 6. Provide closed horizontal stirrups (ACI 11.9.4):

Ah = 0.5 (Asc – An)

Ensure adequate detailing (ACI 11.9.6 & 11.9.7)

Example

Corbel Geometri

Width of corbel, b = 300 mm

Total thickness of corbel, h = 500 mm

Depth to main reinforcement, d = 450 mm

Material Properties

Yield strength of reinforcement, fy = 415 Mpa

Compressive strength of concrete, fc’ = 35 Mpa

Normal weight concrete, λ = 1

Coefficient friction, μ = 1.4 x λ = 1.4

Design Load Data

Factored vertical load, Vu = 370 kN

Distance from face to column, a = 100 mm

Horizontal force, Nu = 75 kN

Strength reduction factor, ϕ = 0.75

Design Procedure

Step 1. Find factored shear Vu and tensile force Nuc

Vu = 370 kN

Nuc_min = 0.2 x 370 = 74 kN

Nuc_act = the larger of 74 kN and 75 kN

= 75 kN

Compute nominal value of shear and tensile force

Vn = 370 / 0.75 = 493.33 kN

Nnc = Nuc / 0.75 = 100 kN

Check section

0.2 x fc’x b x d = 945.0 kN > 493.33 kN

5.5 x b x d = 742.5 kN > 493.33 kN

Section is OK

Step 2. Compute shear-friction reinforcement (ACI 11.7.4.1)

Avf = Vn /μ fy = 493.33 / (1.4×415) = 849.11 mm2

Step 3. Calculate required flexural reinforcement (11.9.3.3)

Mu = Vu av + Nuc (h – d) = 370 x 1000 x 100 + 75 x 1000 (500-450)

Af = Mu / ϕ fy (0.85d) =342.28 mm2

Step 4. Reinforcement to carry tensile force (ACI 11.9.3.4)

An = Nuc / ϕfy = 75×1000 / 0.75×415 =240.96 mm2

Step 5. Required main flexural steel (Asc) is given by (ACI 11.9.3.5 and 11.9.5)

Af + An = 342.28 + 240.96 = 583.25 mm2

2Avf/3 + An = 2/3 849.11 + 240.96 = 807.04 mm2

Asc = 807.04 mm2

Use 3 dia 20 bars

Asc_prov = 3 x 314 = 942 mm2

Step 6. Provide closed horizontal stirrups (ACI 11.9.4):

Ah = 0.5 (Asc – An)= 0.5(807.04 – 240.96) =283.04 mm2

Use 3 dia 8 bars

Ah_prov=2×3×50 = 300 mm2

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Sh = (2×d/3)/3 = (2×450/3)/3 = 100 mm

Detailed reinforcement