Box culvert

7,525 views 71 slides Dec 03, 2019
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Bridge Engineering

Size: 27.94 MB
Language: en
Added: Dec 03, 2019
Slides: 71 pages

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Box Culvert

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Box culverts consisting of two horizontal and two vertical slabs built monolithically are ideally suited for a road or a railway bridge crossing with high embankments crossing a stream with a limited flow . Reinforced concrete rigid frame box culverts with square or rectangular openings are used up to spans of 4 m . The height of the vent generally does not exceed 3 m . Box culverts are economical due to their rigidity and monolithic action and separate foundations are not required since the bottom slab resting directly on the soil , serves as raft slab . For small discharges, single celled box culvert is used and for larger discharges, muhicelled box culverts can be employed . The barrel of the box culvert should be of sufficient length to accommodate the carriageway and the kerbs .

DESIGN LOADS The structural design of a reinforced concrete box culvert comprises the detailed analysis of the rigid frame for moments, shear forces and thrusts due to various types of loading conditions outlined below: 1. Concentrated Loads In cases where the top slab forms the deck of the bridge, concentrated loads due to the wheel loads of the I.R.C. class AA or A type loading have to be considered. If W- Concentrated load on the slab P = Wheel load I= Impact factor e = Effective width of dispersion Then   The soil reaction on the bottom slab is assumed to be uniform . The notations used for the box culvert and the type of loadings to be considered are shown in Fig . 6.1 ( a ) to ( f ).

2 . Uniform Distributed Load The weight of embankment , wearing coat, and , deck slab and the track toad are considered to be uniformly distributed loads on the top slab with the uniform soil reaction on the bottom slab. 3 . Weight of Side Walls The self weight of two side walls acting as concentrated loads are assumed to produce uniform soil reaction on the bottom slab. 4 . Water Pressure Inside Culvert When the culvert is full with water, the pressure distribution on side walls is assumed to be triangular with a maximum pressure intensity of at the base, where w = density of water and h is the depth of flow.  

5 . Earth Pressure on Vertical Side Walls The earth pressure on the vertical side walls of the box culvert is computed according to the Coloumb ’ s theory. The distribution of earth pressure on the side walls is shown in Fig . 6.1 ( e ). 6 . Uniform Lateral Load on Side Walls Uniform lateral pressure on vertical side walls has to be considered due to the effect of live load surcharge. Also trapezoidal pressure distribution on side walls due to embankment loading can be obtained by combining the cases ( 5 )and (6).

DESIGN MOMENTS, SHEARS AND THRUSTS The box culvert is analysed for moments, shear forces and axial thrusts developed due to the various loading conditions by any of the Classical methods such as moment distribution, slope deflection or Column analogy procedures. Alternatively coefficients for moments, shears and thrusts compiled by Victor (Ref-1) are very useful in die computation of the various force components for the different loading conditions. The fixed end moments developed for the six different loading cases are compiled in Table 6.1.

The moment, shear and thrust co- efficients for the various loading cases are shown in table below

The maximum design moment resulting to combination of the various loading cases
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