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Everything You Need To Know About Post

Jun 22, 2023

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Have you ever looked at a building and wondered how it holds together? How can something that tall or big stand on its own like that? Well, it's not standing on its own. With the help of post-tension slabs, high-rise buildings, bridges, and parking lots become reinforced.

We will take a deep dive into everything you need to know about post-tension slabs, from what it is, to how they work to their advantages and disadvantages, and also include some fun facts as we proceed.

So, what are post-tension slabs anyway? Post-tension slab is a concrete slab that uses steel cables to strengthen or reinforce the concrete. Reinforcing the concrete gives it additional strength. The steel cables are placed in the concrete after it has been poured and cured.

The process of pouring and curing concrete creates a force that helps prevent cracking and increases the pressure capacity the slab can hold.

How do post-tensioning slabs work? It is a whole process that starts with placing steel cables. Sometimes, tendons are also used. Anyway, these steel cables or tendons are placed in ducts before concrete is poured into them. The concrete is left to cure, then tensioned using a hydraulic jack.

The force from the hydraulic jack mimics that of cracking concrete under pressure. That way, it counteracts tensile stresses, which could lead to concrete cracking.

Post-tensioning serves as a method of creating stronger concrete by applying pressure that would easily make unreinforced concrete crack. The use of the hydraulic jack tensions the steel cables.

From the information above, you can already tell some of the importance of post-tension slabs when it comes to construction. In this part of the article, we will look at all the good this method of concrete slab reinforcement has brought to the construction world.

Concrete alone is substantial. Now, add more reinforcement to it; it can't crack. Post-tension slabs are made to provide more robust construction solutions. You do not have to spend money when repairing cracked slabs. They serve you for years without fixing them.

Post-tension slabs are essential for projects that need extra strength. These projects include bridges, high buildings, and parking lots, to mention a few.

The constructions mentioned above hold a lot, and that extra reinforcement is much needed.

Another advantage of post-tension slabs is that they span greater distances than conventional concrete slabs. That is why it is used when building bridges or parking lots. Bridges travel great distances by connecting two points, usually across a large water body.

For bridges to complete these heavy tasks, the concrete needs reinforcement.

Parking lots cover a large area and carry the weight of cars. Post-tension slabs make it possible for these constructions to complete what they were designed to do.

Again, bridges. I have used this example a lot but bear with me. Have you ever considered how bridges can hold all that weight? How can they withstand weight from vehicles crossing them every day, hour, or even second for years?

The reinforced concrete slab has made it possible for bridges to hold up and handle all the weight placed on them. Sometimes there are traffic jams on these bridges, and they can still stay intact even when all the weight is at a central position.

Read More: How Much Does a Yard of Concrete Weigh?

There are a lot of application areas for post-tension slabs. In this section, we will look at some I mentioned above, like my dear bridge.

High-rise buildings need all the strength and stability to help them sustain all the weight these buildings carry. The strength and durability of post-tension slabs make them ideal for these tasks. Most high-rise building constructors prefer using post-tension slabs because they offer strength and durability and are also flexible.

Flexibility is essential for high-rise buildings because designers mold them into different shapes and styles to suit their architectural visions. The post-tension slab is flexible enough to manipulate shapes, which traditionally reinforced slabs cannot achieve.

The use of post-tension slabs in the construction of parking garages is widespread. A parking garage must withstand the weight of cars and footprint, all that pressure, and still fight the risk of damage by weather conditions. Therefore, robust concrete is needed, and what better way than a post-tension slab?

The strength and durability of the post-tension slab make it possible for parking lots or garages to withstand the weight placed on them. Parking garages also need the flexibility to stretch that far and create different designs. With the incorporation of post-tension slabs in the parking garage construction, flexibility is achieved.

Well, you all know how I feel about bridges at this point. But it won't hurt to remind you. Most bridges are constructed using the post-tension slab. The slab can resist all the force and pressure applied on the bridge from constant movement.

Another factor that can affect the strength of slabs is weather conditions. Weather damage and strain from heavy vehicles can cause regular repairs, but the repair rate is minimized with post-tension slabs.

Apart from the few structures mentioned above, many other constructions need post-tension slabs to work effectively. Any structure subject to great force is probably made from the post-tension slab. Other structures are airports, stadiums, or any other industrial buildings.

One expected advantage of using post-tension slabs is the creativity factor. With the assistance of these slabs, you can create different designs and styles for your project.

There are several advantages of using post-tension slabs compared to traditional slabs. They include;

The whole point and process of reinforced concrete create a more robust and durable alternative. The post-tension slab is made to increase the durability of all its structures, making them withstand pressure from the elements and ensure the safety of everyone who uses these structures, like bridges…come on, I had to include it.

Instead of adding more and more concrete to make a structure strong, the available concrete is placed in ducts and reinforced from there. This method saves on substantial usage as well as cost. You are guaranteed value for the money used. Post-tension slabs create safe buildings and keep you from using too much money.

The fortification of post-tension slabs happens when the hydraulic jack comes into play. The tool is used to solve the cracking issue making the slab resistant.

Can you imagine how devastating it would be to receive news that there is a crack in the slab after multiple steps have already been completed meaning you have to backtrack and, in some severe cases, start all over again?

With post-tension slabs, you are assured of clean, crisp slabs subject to minimal or no cracking or shrinking.

Although post-tension slabs are revolutionary inventions in construction, some setbacks make it hard for some contractors to be fully onboard with their mechanism.

Creating these slabs is incredibly complex and requires people with particular expertise and skill sets to ensure the installation process runs smoothly.

It needs an expert to ensure the slab is correctly poured into the ducts, then another skilled professional to endure the hydraulic jack tensioning of the cured slab, then remembering someone to provide the slab is fixed correctly.

Post-tension slabs use a lot of material that is costly. The hydraulic jack is expensive, so add the cost of purchasing tendons and steel ducts. Let's remember the cost of hiring labor to construct these slabs and ensure they are perfect at every step.

Many people would instead use traditional reinforced slabs when comparing costs because they are much cheaper than post-tension slabs.

For the work and load post-tension slabs do, they require regular maintenance. More frequent than traditional slabs. Special maintenance officers visit these constructions and conduct various tests to ensure these structures are standard and usually working.

These special maintenance officers also charge fees to conduct these tests and repairs, which adds to the high-cost issue.

Although the flexibility offered by post-tension slabs is more significant compared to traditionally tensioned concrete slabs, it is still considered limited. The flexibility provided by post-tension slabs still limits the number of designs that can be accomplished. Structures need to have flexibility.

Rigid frames are subject to cracks and eventually crumble.

A flexible structure can adapt to changes in the environment, which is why a concrete slab with limited flexibility is not encouraged.

The construction of a post-tension slab requires a five-step process, which I have carefully broken down below:

The first step is pouring the slab. The process usually uses particular slab running techniques like a concrete pump or a concrete truck mixer. The slab is poured into an already laid out area and filled to the designated mark.

The next step is laying cables. The cables are laid on the poured concrete and are applied in the desired design position. These cables are made from solid steel and are placed to support the slab's weight once it has been tensioned and cured.

The next step is tensioning the slab. Tensioning the slab uses a hydraulic jack or any such equipment. The tensioning process strengthens the slab by creating a compressive force that keeps the slab intact. The tensioning process also ensures the slab is smooth, flat, and level.

The next step in the construction process is anchoring the cables. The cables are anchored to the concrete at both sides of the slab. The anchoring process is usually done by special anchorage machines that hold, lift, and secure the cables tightly so they do not slip or engage in unnecessary movements.

Once the cables have been anchored, they will be required to cure. They are left alone to dry and harden for several days to weeks fully. The slab is also needed to undergo cure by being left to dry and harden. The post-tension cables continue to support the slabs while still under tension.

To design post-tension slabs, you need to consider the following factors.

The size and spacing of the cabling will depend on different factors, like the size of the slab, the desired shape and strength and durability, and the expected load. The best results are usually done when the cable sizing is done bigger. However, blogger sizes mean more cost.

The placement of anchor points requires a location where the slabs can withstand the tension of the post-

anchor slabs.

Another important consideration is how thick the post-tension slabs are. The thickness of the slab depends on expected loads, the slab's size, and design. Thicker slabs are more durable. However, to make thicker slabs, you will need to spend more.

When creating a post-slab cable, it is vital to consider the weight of the load to which the wires will be subjected. For this to be fully effective, you need to understand the structure being built and what it is designed to do. From there, you will understand the type of load expected.

As discussed earlier, post-tension slabs require regular maintenance.

Special maintenance officers are hired to conduct inspections of the slaps. These inspections determine the state of the slap, and they usually report their findings.

Once the inspections are done and they have a conclusive report on the slabs’ state, they will repair cables that need it, replace damaged cables entirely, and fit in the new wires.

Post-tension cables are a revolutionary improvement in construction. They create strong and durable structures that stretch over large areas and provide the support needed to hold up these structures.

However, for the slab to hold up its end of the bargain (figuratively and literally), they require regular and efficient maintenance checkups. I hope this article answers all your questions on Everything You Need To Know About Post-Tension Slabs.

Dara Brant is the Managing Editor at Green Building Elements. Prior to joining us she covered alternative energy news and local developments at Your Energy Blog. Dara has a passion for sustainable living and wants to do more than her fair share to help build a better tomorrow for future generations. You can connect with Dara on LinkedIn.

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