In the previous section we completed the discussion on the effects of shear on a homogeneous beam. The discussion that we had about a homogeneous beam, applies to a plain concrete beam (a concrete beam without reinforcement) also. When load is increased in such a beam, tension cracks will develop at the points where tensile stresses are the greatest. In the case of a simply supported beam, it is at the bottom most tension fibre. Once these cracks are formed, we can say that the beam has failed, and it will not take any more load.
Instead of a homogeneous beam, if we are considering a reinforced concrete beam, having steel at the bottom to take up the tension, the situation is quite different. When the first tension cracks form at the bottom most fibres, the loading need not be stopped. The beam can take higher loads because the tension will now be taken by the steel. But when the applied load increases, the shear stress also increases. Because of this, the tension on the principal plane in the particles also increases. We have seen that:
• For a simply supported beam, this tensile stress is maximum for the particles situated at the NA
• At the NA, the tensile stress is equal to q
• At the NA, these planes are inclined at 45o to the vertical
• For simply supported beams, these stresses are maximum near the supports.
So when the applied load on the simply supported beam is increased, the tension is increased not only in the bottom fibres, but also at the NA. When this stress at the NA exceeds the allowable tensile stress of concrete, cracks will develop. These cracks at the NA will be inclined at 45o to the vertical. Because of the 45o inclination, these cracks are also known by the name ‘diagonal tension cracks’. A diagrammatic representation of these cracks is shown in fig.13.24 below. Photographs of such cracks on an actual beam can be seen here.
Fig.13.24
Diagonal tension crack
So we must provide some kind of steel reinforcement to prevent the separation of the concrete along the crack. In other words, we must provide steel reinforcement to keep the two parts together. This is called 'shear reinforcement', and can be provided in three different ways:
• By vertical reinforcement as shown in fig.13.25
• By inclined reinforcement as shown in fig.13.29
• By bent up bars as shown in fig.13.30
Fig.13.25
Vertical shear reinforcement
Fig.13.26
Closed stirrups
It is necessary to provide additional small diameter bars (usually 12 mm dia.) in the compression zone of the beam, in order to properly anchor the stirrups. These bars are known as 'stirrup-holders' or 'stirrup suspenders'. For a doubly reinforced beam, these bars in the compression zone will be already present, and so there is no need to provide additional bars. In the above fig.13.25, stirrups are shown only near the crack at the support, for clarity. In fact they must be provided through out the length of the beam at suitable spacing. This spacing is determined while we design the stirrups. A 3D view of the stirrups is shown in fig.13.27 below
Fig.13.27
3D view of stirrups
In the fig, the stirrups have two legs. Such stirrups are called two-legged stirrups. In some cases, in order to resist greater shear stresses, it becomes necessary to provide several legged stirrups such as four-legged, six-legged etc.,
In the above figures, closed stirrups are shown. In fact, they need not be of closed type. Simple U-shaped open stirrups can also be used. Their free ends should be anchored properly around the stirrup-holders in the compression zone. This type is shown in fig.13.28 below. But in the case of doubly reinforced beams, we know that the stirrup-holders will be replaced by compression steel, and so, to confine the compression steel properly, we must use closed stirrups. Also it is desirable to locate the hooks of the closed stirrups in the compression zone. In this way, the ends of the stirrup bars will be under confinement. This is necessary for improved anchorage and to avoid crack initiation.
The ends of the bar forming the stirrups should be properly anchored in the concrete, to prevent them from opening out. The code has specified the methods by which this anchorage can be given. We will discuss about it in the topic called 'Anchorage for stirrups and ties'.
Yet another point to note is that the hooks of alternate stirrups should be on opposite sides as shown in the following animation.
Fig.13.28
Open stirrups
In the next section, we will see the details about 'Inclined shear reinforcements'.
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