prestressed concrete - philadelphia university
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Prestressed Concrete
Flexural Design of Prestressed Concrete Elements
Instructor:
Dr. Sawsan Alkhawaldeh
Department of Civil Engineering
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General design procedure Design process starts with the choice of a preliminary
geometry. By trial and adjustment, it converge to the final section with
geometrical details of the concrete section and the alignment of the prestressing strands.
The section has to satisfy the flexural (bending) requirements of concrete stress and steel stress limitations.
Other factors such as shear and torsion capacity, deflection and cracking are analyzed and satisfied.
Additional checks are required at the load transfer and limit state at service load, as well as the limit state at failure, with the failure load indicating the reverse strength for overload conditions.
All these checks are needed to ensure that at service load cracking is negligible and the long term effects on deflection are well controlled.
A good understanding of the principles of analysis and the alternative presented thereby significantly simplifies the task of designing the section.
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Sign convention A negative sign (-) is used to denote
compressive stress and a positive sign (+) is used to denote the tensile stress in the concrete section.
A convex or hogging shape indicates negative bending moment (a); a concave or sagging shape indicates positive bending moment (b).
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Loading stages of prestressed concrete
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Stress distribution across the depth of the critical section
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Allowable stresses of concrete
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Summary of equations of stress
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Load-deformation curve of typical prestressed beam
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Decompression stage The decompression stage denotes the
increase in steel strain due to the increase in load from the stage when the effective prestress (Pe) acts alone to the stage when additional load causes the compressive stress in the concrete at the cgs level reduce to zero.
The change in concrete stress due to decompression is:
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Selection of geometrical properties
1. Minimum Section Modulus:
To design or choose the section, a determination of the required minimum section modulus has to be made first.
Determination of the minimum section modulus is dependent on the prestressing steel profile where different equation can be used.
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1.1 Beams with variable tendon eccentricity The section should have section moduli values: The required eccentricity of prestressing tendons at the critical section (Mid span) is: Where is the concrete stress at transfer at the level of the centroid cgc of the concrete section and given as:
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Maximum fiber stresses of Beams with variable tendon eccentricity
(a) Critical section. (b) Support section of simply supported beam.
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1.2 Beams with constant tendon eccentricity The section should have section moduli values: The required eccentricity of prestressing tendons at the critical section is: Where is the concrete stress at transfer at the level of the centroid cgc of the concrete section and given as:
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Maximum fiber stresses of beam with straight tendons
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Service load design example (1) Variable tendon eccentricity
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Service load design example (2) Variable tendon eccentricity with no height limitation
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Service load design example (3) Constant tendon eccentricity
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Envelops for tendon placement
The tensile stress in the extreme concrete fiber under service load conditions cannot exceed the stresses allowable by codes.
It is important to establish the limiting zone in the concrete section; an envelope within which the prestressing force can be applied without causing tension in the extreme concrete fibers.
It can be determined by assuming the allowable stress equals to zero,
Giving 𝑒 =𝑟2
𝑐𝑡 ; Hence, the lower kern point is: 𝑘𝑏=
𝑟2
𝑐𝑡
Similarly, if 𝑓𝑏= 0,
𝑒 =𝑟2
𝑐b ; Hence, the upper kern point is: 𝑘𝑡=
𝑟2
𝑐𝑏
𝑓𝑡= 0 = −𝑃𝑖
𝐴𝑐1 −
𝑒𝑐𝑡
𝑟2
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Envelops for tendon placement
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Limiting eccentricity envelopes
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Limiting eccentricity envelopes
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Prestressing tendon envelope, Example
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