Cortec Corporation
Newequipment 8327 E3a6b7f9 125a 47f1 Bfc9 0ef622120a3f Original
Newequipment 8327 E3a6b7f9 125a 47f1 Bfc9 0ef622120a3f Original
Newequipment 8327 E3a6b7f9 125a 47f1 Bfc9 0ef622120a3f Original
Newequipment 8327 E3a6b7f9 125a 47f1 Bfc9 0ef622120a3f Original
Newequipment 8327 E3a6b7f9 125a 47f1 Bfc9 0ef622120a3f Original

Corrosion Technology is Key to Preventing Collapsing Structures

Sept. 27, 2018
By using MCI technology in severely corrosive environments, structures will have a stronger resistance to corrosion and therefore longer durability.

According to the engineering regulations, the durability and design of the structure lifetime is around 50 years. Its lifetime is extended by regular maintenance or otherwise it should be demolished and rebuilt. By using MCI technology in severely corrosive environments, structures will have a stronger resistance to corrosion and therefore longer durability. Increased durability means fewer repairs, enhanced structural integrity and a longer service life, all leading to greater sustainability.

Corrosion is a natural force that can be life threatening and it's a huge problem for engineers who frequently use metal products in their structures. The collapsing of the Morandi bridge in Genoa, Italy demonstrated how neglecting this powerful force can have tragic consequences.

Engineers brought out numerous concerns about the bridge, which was built in 1967, including its unusual concrete-encased common steel cables. The designer of the Genoa bridge warned four decades ago that it would require constant maintenance to remove rust, given the effects of corrosion on the concrete from sea air and pollution.

“As this reinforced and prestressed concrete bridge has been there for more than 35 years, it is very possible that corrosion of tendons or reinforcement is a contributory factor,” said Ivana Liposcak, Cortec’s MCI  technical support manager for Europe. “The long-term behavior of viaducts subjected to heavy traffic and situated in aggressive environment shows that at the time of planning obviously many concepts about the sustainability of the bridge were not known and considered. Due to the vibration in concrete, microcracks occur, through which the moisture leads to oxidation and corrosion of steel and in that way, structure gradually loses its capacity due to corrosion,” noted Liposcak.

Crumbling infrastructure is a worldwide problem

In the spring of 2000 in North Carolina, as people were making their way back to the parking lot across a bridge, concrete and steel walkway snapped in half. After an inspection, it was determined that all 11 steel cables that were holding the bridge together were corroded, and the bridge bustled under the weight. The corrosion was caused by too much calcium chloride, an inorganic salt compound that’s highly corrosive to steel, mixed into the grout that cemented the bridge’s steel cables in place. Nearly 50 lawsuits were filed against the speedway and the construction company with settlements of millions of dollars.

A report from the American Road & Transportation Builders Association states that more than 15% of that country’s bridges are “structurally deficient”. The difficulty is that concrete, or rather the steel used to reinforce it, can fail in a number of ways. Salt, ice, and the pounding of weather can cause fractures in the concrete’s surface. Once the water reaches the steel reinforcing or tendons, it corrodes them. This enlarges the cracks, which can cause the concrete to fall apart. “Other factors also compound the deterioration of bridges, such as a constant traffic,” says Liposcak, “this is a problem for bridges designed 50 years ago, when traffic was lower, cars were smaller and lorries much lighter." Harsh weather conditions, such as heat, cold, floods, and high winds buffeting all contribute to corrosion of bridges.

How do we build sustainable and durable structures?

During last two decades there have been huge advances in technology to extend the lifespan of structures and avoid possible tragedies happening. One of the most efficient uses of migrating corrosion inhibitors (MCI) are when applied directly during construction phase as well as a part of the maintenance repair system in existing structures. For prestressed structures for bridges, MCI’s are recommended for the protection of prestressed cables before grouting such as Cortec’s MCI 309. 

Sustainable construction has become a goal for owners across the globe. An often overlooked aspect is the durability and service life of the final structure. However, this is undoubtedly one of the main factors influencing structural sustainability. MCI inhibitors are  made from a renewable raw material, enabling users to earn certain LEED credits.

There are many current cases of using migrating inhibitor technology in projects around the word such as erecting the new Frederikssund bridge in Denmark. The aim is to replace the old bridge built in 1935 by providing an alternative to the only currently active bridge over the fjord. The project includes design and construction of an 8 km-long dual-carriageway highway, comprehensive of a bridge over the Roskilde Fjord. MCI 309 is used for corrosion protection of PT concrete segments.

MCIs are based on amine technology. They are classified as mixed inhibitors, meaning they affect both anodic and cathodic portions of a corrosion cell. MCI is applied in many forms including as a concrete admixture or a topical treatment. It moves as a liquid through the concrete matrix via capillary action and migrates in a vapor phase throughout the concrete pore structure. When MCI comes in contact with embedded metals, it has an ionic attraction to it and forms a protective molecular layer. This film prevents corrosive elements from further reacting with the reinforcement and also reduces existing corrosion rates, greatly extending concrete service life.

Migrating corrosion inhibitors form a protective layer on the surface of embedded steel reinforcement.

The Maslenica Bridge in Croatia is one of the largest bridges of its type with an arc of 200 meters (218.7 yd) in diameter. Because of the aggressive environment of changing temperatures, constantly fluctuating humidity, and strong wind containing salt from seawater, reinforcing steel had started to corrode, causing concrete spalling. To restore the bridge and prevent future corrosion from happening, all spalling concrete was water-blasted off, along with dirt and corrosion on the rebar. CorrVerter MCI Rust Primer was brushed on exposed rebar to passivate the metal from further corrosion, and MCI 2020 was applied to the entire concrete structure using an airless sprayer to prevent any potential corrosion that was not apparent.

If the world was made of Lego bricks, building of bridges would be perfected and perhaps they would never collapse. In the real world, every project is different. Geology, weather conditions, volume of traffic, and available construction material affect design and construction. Today, we are lucky to have advanced corrosion protection to properly apply for the benefit of all of us.

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