Session 10: Members Analysis under Flexure (Part II)2015/3/18 1 BETON PRATEGANG TKS - 4023 Dr.Eng....
Transcript of Session 10: Members Analysis under Flexure (Part II)2015/3/18 1 BETON PRATEGANG TKS - 4023 Dr.Eng....
2015/3/18
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BETON PRATEGANG TKS - 4023
Dr.Eng. Achfas Zacoeb, ST., MT.
Jurusan Teknik Sipil
Fakultas Teknik
Universitas Brawijaya
Session 10:
Members Analysis under Flexure (Part II)
Introduction
The analysis of flexural members under service loads
involves the calculation of the following quantities:
Cracking moment.
Location of kern points.
Location of pressure line.
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Cracking Moment The cracking moment (Mcr) is defined as the moment
due to external loads at which the first crack occurs in a
prestressed flexural member. Considering the variability
in stress at the occurrence of the first crack, the
evaluated cracking moment is an estimation and
important in the analysis of prestressed members.
Cracking Moment (cont’d) Based on the allowable tensile stress the prestress members are classified into three types as:
1. Type 1: Full Prestressing, when the level of prestressing is such that no tensile stress is allowed in concrete under service loads.
2. Type 2: Limited Prestressing, when the level of prestressing is such that the tensile stress under service loads is within the cracking stress of concrete.
3. Type 3: Partial Prestressing, when the level of prestressing is such that under tensile stresses due to service loads, the crack width is within the allowable limit.
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Cracking Moment (cont’d) For Type 1 and Type 2 members, cracking is not
allowed under service loads. Hence, it is imperative to
check that the cracking moment is greater than the
moment due to service loads. This is satisfied when the
stress at the edge due to service loads is less than the
modulus of rupture.
Cracking Moment (cont’d) The modulus of rupture is the stress at the bottom edge
of a simply supported beam corresponding to the
cracking moment (Mcr). The modulus of rupture is a
measure of the flexural tensile strength of concrete and
measured by testing beams under 4 point loading
including the reaction. The modulus of rupture (fcr) is
expressed in terms of the characteristic compressive
strength (fck) of concrete in N/mm2.
(Eq. 13)
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Cracking Moment (cont’d) FIg. 9 shows the internal forces and the resultant stress
profile at the instant of cracking.
Fig. 9 Internal forces and resultant stress profile at cracking
Cracking Moment (cont’d) The stress at the edge can be calculated based on the
stress concept and the cracking moment (Mcr) can be
evaluated by transposing the terms as Eq. 14. This
equation expresses Mcr in terms of the section and
material properties and prestressing variables.
(Eq. 14)
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Kern Points When the resultant compression (C) is located within a specific zone of a section of a beam, tensile stresses are not generated. This zone is called the kern zone of a section. For a section symmetric about a vertical axis, the kern zone is within the levels of the upper and lower kern points. When the resultant compression (C ) under service loads is located at the upper kern point, the stress at the bottom edge is zero. Similarly, when C at transfer of prestress is located at the bottom kern point, the stress at the upper edge is zero. The levels of the upper and lower kern points from CGC are denoted as kt and kb, respectively.
Kern Points (cont’d) Based on the stress concept, the stress at the bottom edge corresponding to C at the upper kern point , is equated to zero. Fig. 10 shows the location of C and the resultant stress profile when compression is at upper kern point.
Fig. 10 Resultant stress profile (compression at upper kern point)
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Kern Points (cont’d) The value of kt can be calculated by equating the stress at the bottom to zero as follows: (Eq. 15)
Eq. 15 expresses the location of upper kern point (kt) in terms of the section properties. Here, r is the radius of gyration and yb is the distance of the bottom edge from CGC.
Kern Points (cont’d) Similar to the calculation of kt, the location of the bottom kern point, kb can be calculated by equating the stress at the top edge to zero. Fig. 11 shows the location of C and the resultant stress profile when compression is at lower kern point.
Fig. 11 Resultant stress profile (compression at lower kern point)
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Kern Points (cont’d) The value of kt can be calculated by equating the stress at the top to zero as follows:
(Eq. 16) Eq. 16 expresses the location of lower kern point (kb) and yt is the distance of the top edge from CGC.
Cracking Moment using
Kern Points
The kern points can be used to determine the cracking
moment (Mcr). The cracking moment is slightly greater
than the moment causing zero stress at the bottom. C is
located above kt to cause a tensile stress fcr at the
bottom. The incremental moment is fcrI/yb. Fig. 12 shows
the shift in C outside the kern to cause cracking and the
corresponding stress profiles.
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Cracking Moment using
Kern Points (cont’d)
Fig. 12 Resultant stress profile at cracking of the bottom edge
Cracking Moment using
Kern Points (cont’d)
The cracking moment can be expressed as the product
of the compression and the lever arm. The lever arm is
the sum of the eccentricity of the CGS (e) and the
eccentricity of the compression (ec). The later is the sum
of kt and z, the shift of C outside the kern.
(Eq. 17)
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Cracking Moment using
Kern Points (cont’d)
Substituting C = Pe, kt = r2/yb and r2 = I/A, Eq. 17
becomes same as the previous expression of Mcr (Eq.
14).
(Eq. 18)
Pressure Lines The pressure line in a beam is the locus of the resultant
compression (C) along the length. It is also called the
thrust line or C-line. It is used to check whether C at
transfer and under service loads is falling within the kern
zone of the section. The eccentricity of the pressure line
(ec) from CGC should be less than kb or kt to ensure C in
the kern zone.
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Pressure Lines (cont’d) The pressure line can be located from the lever arm (z)
and eccentricity of CGS (e) as follows. The lever arm is
the distance by which C shifts away from T due to the
moment. Subtracting e from z provides the eccentricity
of C (ec) with respect to CGC. The variation of ec along
length of the beam provides the pressure line.
(Eq. 19)
Pressure Lines (cont’d) A positive value of ec implies that C acts above the
CGC and vice-versa. If ec is negative and the numerical
value is greater than kb (that is |ec| > kb), C lies below
the lower kern point and tension is generated at the top
of the member. If ec > kt, then C lies above the upper
kern point and tension is generated at the bottom of the
member.
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Pressure Lines (cont’d) Pressure Line at Transfer
The pressure line is calculated from the moment due to the self weight. Fig. 13 shows that the pressure line for a simply supported beam gets shifted from the CGS with increasing moment towards the centre of the span.
Fig. 13 Pressure line at transfer
Pressure Lines (cont’d) Pressure Line under Service Loads
The pressure line is calculated from the moment due to the service loads. Fig. 14 shows that the pressure line for a simply supported beam gets further shifted from the CGS at the centre of the span with increased moment under service condition.
Fig. 14 Pressure line under service loads
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Pressure Lines (cont’d) Limiting Zone
For fully prestressed members (Type 1), tension is not allowed under service conditions. If tension is also not allowed at transfer, C always lies within the kern zone. The limiting zone is defined as the zone for placing the CGS of the tendons such that C always lies within the kern zone.
Pressure Lines (cont’d) For limited and partially prestressed members (Type 2 and Type 3), tension is allowed at transfer and under service conditions. The limiting zone is defined as the zone for placing the CGS such that the tensile stresses in the extreme edges are within the allowable values.
Fig. 15 Limiting zone for a simply supported beam
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Problem
with no eccentricity at the ends. The
live load moment due to service loads at mid-span (MLL)
is 648 kNm. The prestress after transfer (P0) is 1600 kN.
Grade of concrete is 30 MPa. Assume 15% loss at
service.
For the post-tensioned beam with a
flanged section as shown, the profile of
CGS is parabolic,
Question
Evaluate the following quantities:
a. Kern levels
b. Cracking moment
c. Location of pressure line at mid-span at transfer and at service.
d. The stresses at the top and bottom fibres at transfer and at service.
Compare the stresses with the following allowable stresses at transfer and at service.
For compression, fcc = – 18.0 N/mm2
For tension, fct = 1.5 N/mm2
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Solution
Calculation of geometric properties
The section is divided into three rectangles for the computation of the geometric properties.
Area of the section, A:
A1 = 500X200 = 100,000 mm2
A2 = 600X150 = 90,000 mm2
A3 = 250X200 = 50,000 mm2
A = A1+A2+A3 = 240,000 mm2
Solution (cont’d)
Location of CGC from the bottom side,
Therefore,
Eccentricity of CGS at mid-span,
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Solution (cont’d)
Moment of inertia, I1 about axis through CGC:
Moment of inertia, I2 about axis through CGC:
Moment of inertia, I3 about axis through CGC:
Solution (cont’d)
Moment of inertia of the section:
Square of the radius of gyration:
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Solution (cont’d)
a. Kern levels of the section
Solution (cont’d)
b. Calculation of cracking moment
Moment due to self weight (MDL):
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Solution (cont’d)
Modulus of rupture (fcr):
Moment of cracking (Mcr):
Solution (cont’d)
Live load moment corresponding to cracking (MLL cr):
Since the given live load moment (648.0 kNm) is less
than the above value, the section is uncracked ⇒ the
moment of inertia of the gross section can be used for
computation of stresses.
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Solution (cont’d)
c. Calculation of location of pressure line at mid-span
At transfer
Since ec is negative, the
pressure line is below CGC.
Since the magnitude of ec is
greater than kb, there is
tension at the top.
Solution (cont’d)
At transfer
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Solution (cont’d)
At service
Since ec is positive, the
pressure line is above CGC.
Since the magnitude of ec is
greater than kt, there is
tension at the bottom.
Solution (cont’d)
At service
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Solution (cont’d)
d. Calculation of stresses
The stress is given as follows:
Solution (cont’d)
Calculation of stresses at transfer (P = P0):
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Solution (cont’d)
Stress at the top fibre (at transfer):
Solution (cont’d)
Stress at the bottom fibre (at transfer):
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Solution (cont’d)
Calculation of stresses at service (P = Pe):
Solution (cont’d)
Stress at the top fibre (at service):
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Solution (cont’d)
Stress at the bottom fibre (at service):
Solution (cont’d)
The stress profiles:
The allowable stresses are as follows:
For compression, fcc = – 18.0 N/mm2
For tension, fct = 1.5 N/mm2.
Thus, the stresses are within the allowable limits.
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Thanks for Your Attention and
Success for Your Study!