Understanding the Transfer of Loads from Slab to Beams

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The transfer of loads from a slab to beams is controlled by the slab's geometrical dimension and the direction of reinforcements. The load of the slab, including self-weight, live load, and imposed dead load, are distributed over the beams on their sides.

The slab loads are expressed in weight per unit area, whereas the loads of beams are expressed in units of weight per length of the beam.

If the slab has regular dimensions, the load transfer can be carried out easily and quickly. However, if it has an irregular shape, it is recommended to use suitable programs such as SAP2000, SAFE, and ETABS. 

One-way Slab

The load of the one-way slab, which has a rectangular shape, is divided equally between adjacent beams. The interior beam takes half of the total load of a slab on each side.

If a slab is supported on two sides only or supported on all four sides, but the longer side to shorter side ratio is greater than 2, it is termed as one-way slab, see Figure-2.

Two-way Slab

Loads on a two-way slab are transferred to all beams on all the sides. So, each beam supports an amount of the load from the slab. The slab is commonly divided into trapezoidal and triangular areas by drawing lines from each corner of the rectangle at 45 degrees.

The beam's distributed load is computed by multiplying the segment area (trapezoidal or triangular area) by the slab's unit load divided by the beam length. For an interior beam, the portion of the other side's slab weight is estimated in a similar way and added to the previous one, i.e., the slab's load from the other side of the beam. So, interior beams take loads from both the sides.

Example

The slab of the figure shown below has a thickness of 150 mm and in addition to its own weight, it supports 0.85 KN/m² partition, and a live load of 2.4 KN/m². Transfer the load of the slab to the beams on all four sides.

Solution:

Self-weight of the slab= slab thickness* concrete unit weight

                                          = 0.15*24= 3.6 KN/m²

Total Dead load on Slab= 3.6+0.85= 4.45 KN/m²

One can distribute service load (unfactored load) to the beam or ultimate distributed load to the slab; use factored load for both dead load and live load of the slab according to the specifications of ACI 318-19.

In this example, we use different load factors and then use load combination to calculate ultimate distributed load on the slab. After that, the ultimate distributed load is transferred to the beams.

Ultimate distributed load (Wu)= 1.2*dead load+ 1.6*live load

Ultimate distributed load (Wu)= 1.2*4.45+1.4*2.4= 8.7 KN/m²

Load of slab on beam (4 m)= area of triangle*Wu

                                                     = 4*8.7=34.8 KN

Uniform distributed load of slab on beam (4 m) = 34.8/4= 8.7 KN/m

Load of slab on beam (4 m)= area of trapezoidal*Wu

                                                     = 8*8.7=69.6 KN

Uniform distributed load of slab on beam (6 m) = 69.6 /6= 11.6 KN/m

Complex-geometry Slab

Finite element modeling should be used to distribute the load of a slab with complex geometry to a beam. For this purpose, computer programs like SAP200, SAFE, and ETABS can be used. This method can also be considered for slabs with regular geometry.

FAQs

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