Magnesite flooring, a type of flooring material made from magnesium oxide and other additives, has been a popular choice in the Australian building industry for decades due to its durability, versatility, and cost-effectiveness. However, while it has demonstrated numerous advantages, it also presents significant downsides, such as concrete spalling or concrete cancer, which can be a substantial concern for building owners.
This article delves into the world of magnesite flooring, its application in Australia’s building industry, its drawbacks, the issue of concrete spalling, and potential remediation techniques.
Usage in the Australian Building Industry:
Magnesite flooring, also known as magnesite cement flooring, has been utilized extensively in the Australian building industry since the mid-2000s. It was initially popular due to its exceptional fire-resistant properties and affordability.
It found applications in both residential and commercial buildings, including apartments, offices, schools, and commercial spaces. Its versatility allowed it to be applied over various substrates, creating a seamless and durable surface.
Additionally, magnesite flooring was lauded for its acoustic and thermal insulation qualities, contributing to comfortable indoor environments.
Downsides of Magnesite Flooring:
Magnesite flooring is susceptible to moisture penetration. Magnesite is hygroscopic, meaning it readily absorbs moisture from the environment. This can lead to gradual degradation of the material, causing it to swell, crack, and eventually delaminate from the substrate.
Moreover, the moisture-absorbing property of magnesite flooring can result in the corrosion of underlying steel reinforcement, further compromising the structural integrity of the building.
Concrete Spalling/ Concrete Cancer Caused by Magnesite Flooring:
One of the most alarming issues associated with magnesite flooring is concrete spalling and /or concrete cancer. This term describes the progressive deterioration of concrete due to the presence of moisture and the alkaline nature of magnesite.
As magnesite absorbs moisture, it generates an alkaline solution that, over time, attacks the concrete, leading to its disintegration. This negative impact can have severe consequences, including compromising the building’s structural stability and safety.
Remediation Techniques for Concrete Spalling:
Addressing concrete spalling caused by magnesite flooring requires comprehensive remediation strategies. Remedial engineers play a crucial role in assessing the extent of the damage and implementing appropriate solutions. Some common techniques include:
Removal and Replacement:
In severe cases, the affected magnesite flooring and compromised concrete must be entirely removed and replaced. This process involves careful demolition, surface preparation, and installation of a new flooring system.
Surface Coatings:
Applying specialized surface coatings can help protect the concrete from moisture intrusion. These coatings create a barrier that prevents the alkaline solution generated by magnesite from reaching the concrete.
Drying and Moisture Mitigation:
Drying out the affected area and implementing moisture mitigation techniques can help halt the progression of concrete deterioration. Dehumidification and proper drainage systems may be installed to prevent further moisture ingress.
Concrete Repair:
Remedial engineers can employ various concrete repair techniques, such as shotcrete, epoxy injection, and polymer-modified mortars, to restore the structural integrity of damaged concrete sections.
Encapsulation:
In some cases, encapsulating the magnesite flooring with a compatible overlay system can prevent further interaction between magnesite and concrete, effectively containing the issue.
Magnesite flooring has left a significant mark on the Australian building industry, offering both benefits and challenges. Its durability, fire resistance, and affordability have made it a popular choice in the past, but its susceptibility to moisture-related issues, particularly concrete spalling, has raised concerns over recent years.
Remedial engineers play a vital role in assessing and mitigating the damage caused by magnesite-related problems. By employing appropriate remediation techniques, they can help restore structural integrity, ensure occupant safety, and prolong the lifespan of affected buildings.
As the industry advances, the lessons learned from magnesite flooring serve as a reminder of the importance of understanding material properties and implementing effective maintenance and remediation practices.
Follow Techdee for more!