Renforcement concrete design (ACI-code 2019)
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Renforcement concrete design (ACI-code 2019) 2- Design the beam for the slab shown below. The beam...
RENFORCEMENT CONCRETE DESIGN (ACI-Code 2019). Reinforced Concrete Design Example 1: Using the ACI-Code approximate structural analysis, design for a warehouse, a continuous one-way solid slab supported on beams 4.0 m apart as shown in Figure. Assume that the beam webs are 30 cm wide. The dead load is 3 kN/m² in addition to the own weight of the slab, and the live load is 3 kN/m². Use fcº=28MPa, fy= 420MPa 8.0 m 4.0 m 4.0 m 4.0 m
A reinforced concrete beam with dimensions (300 mm * 800 mm) subjected to a service dead load moment (MD=500 kN.m) and a service live load moment (ML = 400 kN.m). Design the section as a double reinforced section (the dimensions can't be increased). Place the compression reinforcement at 65 mm from the compression face. Compressive strength of concrete; fe 28 MPa, yielding stress of reinforcement; fy= 420 MPa. Assume 30 mm to be used in the tension (two layers), 26...
A reinforced concrete beam with dimensions (300 mm * 800 mm) subjected to a service dead load moment (MD= 500 kN.m) and a service live load moment (ML = 400 kN.m). Design the section as a double reinforced section (the dimensions can't be increased). Place the compression reinforcement at 65 mm from the compression face. Compressive strength of concrete; fc = 28 MPa, yielding stress of reinforcement; fy= 420 MPa. Assume 30 mm to be used in the tension (two...
reinforced concrete design , ACI code Shear Strength of Flexural Members Design for shear forces The simply supported beam shown is subjected to ultimate (factored) distributed and concentrated loads 1. Determine the shear capacity of concrete at the critical section according to ACI318-14 detailed method in Table 22.5.5.1. Design the shear reinforcement and determine the locations on the beam shear force diagram where this shear reinforcement should be placed. 2. 3. Determine the locations within the beam where minimum shear...
Design a rectangular beam section for the load given W(dead) =29.40kN/m, W(live) = 43.20kN/m, L1=4.82m, L2= 1.5m, use row(p)=0.18f'c/fy. Beam weight is not included in the loads shown. fy = 414 MPa, f’c = 28 MPa. Live loads are to be placed where they will cause the most severe conditions at the sections being considered. Select the beam size for the largest moment (positive or negative), and then select the steel required for maximum positive and negative moment. Assume concrete...
Q3 (50 pts): Design the concrete slab shown below for bending moment: Wu=0.13 k/At including self weight 12' f. -4,000 psi fy = 60 ksi
Q3 (50 pts): Design the concrete slab shown below for bending moment: Wu=0.13 k/At including self weight 12' f'c = 4,000 psi fy=60 ksi
Q3 (50 pts): Design the concrete slab shown below for bending moment: Wu= 0.13 k/ft including self weight 12' fe-4,000 psi fy=60 ksi
The low strength concrete floor slab is integrated with a wide- flange A-36 steel beam using shear studs (not shown) to form the composite beam. (Figure 1) Part A If the allowable bending stress for the concrete is (Gallow)con = 10 MPa and allowable bending stress for steel is allow)st = 165 MPa, determine the maximum allowable internal moment M that can be applied to the beam. Express your answer with the appropriate units. Figure 1 of 1 H HÅ...
Design an interior one-way slab for the figure and load shown below. Given: fc = 4000 psi, fy 60,000 psi The only dead load is the weight of the slab Do not use the ACI Code's minimum thickness for deflection Table 7.3.II Steel percentage p 0.0143 is given in the figure. Finally sketch the slab and show the approximate bar location ρ=0.0143 24