This document provides an overview of post-tensioned concrete slabs. It discusses how PT slabs use high-strength steel strands in tension to compress the concrete and allow for thinner slab thicknesses. This makes PT slabs more efficient and economical compared to reinforced concrete, allowing for longer spans. Examples are given showing how PT slabs offer reductions in material usage, embodied carbon, and cost. Case studies demonstrate real-world applications of PT slab construction.
3. Introduction
Post-tensioned (PT) slabs are typically flat slabs. PT slabs offer the thinnest slab type,
as concrete is worked to its strengths, mostly being kept in compression. Longer
spans can be achieved due to pre-stress, which can also be used to counteract
deflections.
Post-tensioned slabs use high-strength tensioned steel strands to compress the slabs,
keeping the majority of the concrete in compression. This gives a very efficient
structure which minimizes material usages and decreases the economic span range
when compared to reinforced concrete.
4. Sustainable Construction with Post-Tensioned Slabs
Embodied Energy and Embodied Carbon
Research conducted for the Concrete Centre
has highlighted that the difference between
frame systems is not substantial. This
research also demonstrated that carbon
savings are more significantly influenced by
how the design and specification are
optimized rather than the choice of framing
material.
carefully designed and specified post-
tensioned frame solutions can offer the lowest
achievable levels of embodied CO2 for
minimum depth.
5. Opportunities for the use of post-tensioning
Resource efficiency
Typically 20% reduction in concrete volume.
The reinforcement requirement of a typical PT slab is 40% of the equivalent RC slab.
Carbon/Low Waste
100% secondary aggregate is also viable.
Reinforcing bar itself is typically from 95-100% recycled sources while the strand
content may be as much as 30% recycled.
Flexibility and Adaptability
Allow high thermal mass.
Long spans allow for future flexibility and adaptation.
6. What is post-tensioning?
Concrete has a high compressive strength, but has low tensile strength. Traditional
reinforcement is often used to give concrete more ductility because the steel resists
the tensile forces in the element. In post-tensioned structures high-strength steel is
used, which is tensioned against the concrete. This puts the concrete into
compression, utilizing more of the inherent strength and enabling thinner concrete
sections to be used.
8. Comparison Between RC & PT slab
• Based on span depth ratio
Floor System
Typical span Depth ratio
PT RC
One Way 48 21-28
Two Way 45 33
One Way slab with drop panel 50 36
9. Comparison Between RC & PT slab
• Based on Costing
Bay
size
Slab Thickness
Rebar per sft
area
PT steel per sft
area
Cost per sft area
(U$)
PT RC PT RC PT RC PT RC
30’x30’ 8in 10in 0.8 kg 2 kg 0.5 kg 0 8.05 9.56
10. Why use post-tensioning slab?
• Long-spans – post-tensioned concrete can span further than reinforced concrete and
competes economically with steel structures. Long spans reduce the number of columns and
foundations and increase flexibility for space-planning.
• Minimum floor thickness – Post-tensioning has the minimum structural thickness of any floor
system. This reduces self-weight and the overall height of the building.
• Openings – post-tensioned slabs can readily accommodate openings. Smaller holes can be
formed between tendons, and larger holes can be designed into the system.
• Performance – post-tensioning comes with all the benefits of concrete such as good vibration
control, fire resistance and sound insulation.
• Sustainable – The thermal mass of the concrete can be utilised to moderate the temperature
fluctuations in the building. Posttensioning also reduces the materials used in the structure.
Longer spans offer future flexibility – increasing the potential life-span of the building.
11. Post-tensioning market
The use of post-tensioning (PT) has
increased dramatically over the last
decade. There are now many companies
which offer postn tensioning supply and
installation services in many countries.
12. Some Case Studies
Whitmore High School, UK
The new 9,550m² secondary school building has
been constructed with three storey structure has
300mm thick PT slabs.
Whitestown Way Shopping Centre, Dublin
Originally conceived as RC, the decision to
switch to post-tensioned concrete has saved
in excess of €1M, principally in reduced
reinforced tonnage, decreased concrete
volumes and simplified formwork.
13. Some Case Studies
Motor City - Dubai - U.A.E.
ADG value engineered a foundation alternative for
this mixed use residential development in Dubai. The
Post Tensioned Raft system was the first purely PT
raft to be approved by Dubai municipality. The
superstructure design was completed by ADG, being
constructed with some 2500 tons of post tensioning
Morrison’s Distribution Warehouse
Key Facts:
• Total area of ground slab, 42000 sq.m
• A 180mm thick flat slab was used.
• Significant reduction in construction joints and movement
joints.
• Superior control of concrete shrinkage and durability .
15. References
• The Structural Engineer: Volume 90, issue 5, may 2012, pp32-40
• www.pta.uk.com
• The post tensioning Association, GN04
• The post tensioning Association, GN03