International Syalons are delighted to receive two prizes at the British Ceramic Confederation health and safety Pledge conference and awards event in Stoke-on-Trent on 14th October 2021.

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Advanced ceramic applications are far-reaching, constantly evolving, and continue to drive innovation in engineering and technology. Different types of advanced ceramics each have specific characteristics, offering a high-performance, economical alternative to traditional materials such as metals, glass, and plastics.

Effective manufacturing of finished aluminium products or aluminium castings relies on efficient transferring of large amounts of liquid and solid metal. However, within even the biggest foundries and cast houses there are often instances where operators need to focus on smaller quantities of molten metal and the means of transferring it efficiently and safely.

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Aluminium is an extremely versatile metal with a wealth of applications in a variety of domains, made possible thanks to a range of specialist and technical foundry products that enable them. It is one of the most broadly used metals, second only to iron. This is largely due to its low melting point, malleability at room temperature, and its low density. Aluminium is corrosion resistant and is a good conductor of both electricity and heat.

Light metals are those which have a relatively low density. Some of the most commonly used light metals are aluminium, titanium, and magnesium.

As industries across the globe require increasingly high product performance, molten metal quality is becoming more and more important. Aluminium is the second-most consumed metal across the globe and the market produces more than 50 million tons of aluminium every year.

Foundry operations are inherently dangerous. The production of metal castings is associated with numerous health hazards, including exposure to chemicals, gases, heat, and non-ionizing radiation. It is not uncommon for iron and steel workers to be chronically exposed to polycyclic aromatic hydrocarbons (PAHs), respirable silica, or carbon monoxide (CO). Beyond exposure issues, there are also concerns surrounding molten metal/water explosions and catastrophic component failure due to corrosion, thermal strain, or wear.

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Advanced ceramic materials continue to push engineering frontiers, and while there may be an open question about the true sustainability of technical materials from alumina (Al₂O₃) to zirconia (ZrO), there is no doubt about their impact on clean technology. We have spent the last few articles discussing the impact of advanced ceramic manufacturing on our environment, and their long-term viability in terms of pollution. In this article, we will explore the many exciting successes of sustainable advanced ceramic innovations and applications.

Advanced ceramic manufacturing is a complex multi-step process centring on the consolidation and sintering of raw mineralogical feedstocks. Regardless of the type of ceramic (oxide or non-oxide), or the complexity, shape, size, and structure of the finished part, it is this densification stage of production that unlocks the outstanding thermomechanical properties of technical ceramic materials. It is also, by far, the most energy-intensive link in the advanced ceramics manufacturing chain.

Technical ceramics have become a mainstay among advanced engineering materials, replacing heavy duty metallic alloys and even refractories in many challenging applications and industries. This stems from their good all-round thermomechanical properties, but can also be attributed to incremental improvements in designing with ceramics and ceramic manufacturing. So, what impact does this shift towards specialist, high-performance material solutions have on corporate and social responsibilities, and sustainability initiatives?Continue reading→