Andrea Incardona, material engineer at materials testing instrumentation manufacturer Instron, explores the relationship between lightweighting and durability.
The drive towards lightweight materials is evident across multiple industries, with engineers increasingly adopting composites, advanced polymers and hybrid materials to reduce weight while maintaining performance. However, lightweighting is about far more than simply preserving strength. As materials become lighter and designs more complex, manufacturers must ensure components can resist fatigue, impacts, wear and environmental stresses throughout their service life.
The hidden challenge of lightweight design
Lightweighting is rarely a straightforward material substitution exercise. Every design decision involves balancing weight, cost, manufacturability, stiffness, durability and safety. The growing importance of these materials is reflected in the AVK Market Report 2024, published in March 2025, which found that transport applications account for almost 50 per cent of European composites production.
While many lightweight materials offer excellent performance under normal operating conditions, they may respond very differently when exposed to dynamic loads.
In-service loading conditions rarely mirror those encountered during laboratory testing. Materials can be exposed to impacts, shock loads and other dynamic events that introduce complex stress states and failure mechanisms not always captured through conventional static testing.
For advanced composites in particular, the consequences of impact can be difficult to identify. Unlike metals, which exhibit visible dents or deformation, composite materials can sustain significant internal damage without displaying this on the surface. Delamination, matrix cracking and fibre breakage may remain hidden beneath the outer layers, reducing structural integrity without obvious visual warning signs.
With this in mind, understanding how lightweight materials behave under dynamic loading becomes increasingly important. A material that performs well in ideal conditions may not necessarily provide the durability required in service.
Looking beyond strength
One of the reasons why predicting real-world performance can be challenging is because higher strength does not automatically translate to better performance. Engineers must also understand material toughness and how damage develops during an impact event. Two materials may exhibit similar strength values on a datasheet, yet behave very differently when subjected to sudden loading, as material properties can change drastically at high strain rates.
Failure mode is often just as important as ultimate strength. In automotive applications, components may be designed to absorb energy progressively during a collision, while electronics manufacturers need confidence that critical components will continue functioning after accidental drops or impacts. Understanding whether a material fails progressively or catastrophically can have a significant influence on product safety and reliability.
Proving performance in the real world
This is where materials testing plays a critical role. Understanding how a material absorbs energy, develops damage and ultimately fails requires more than static material data alone. Lightweight materials are often selected based on properties such as tensile strength, stiffness and density, but these values do not always predict how a material will behave during an impact event.
For advanced composites in particular, performance can be influenced by fibre architecture, matrix material, layup sequence, component geometry and impact conditions. Impact testing helps engineers evaluate critical characteristics such as toughness, energy absorption and failure mode under dynamic loading conditions. Specifically, tensile impact testing is particularly valuable because it measures the energy required to initiate and propagate failure under dynamic loading conditions.
For advanced composite structures, compression-after-impact testing can reveal how internal damage affects residual strength following an impact event. To evaluate these effects, instrumented drop-weight impact systems such as Instron’s 9400 Series drop towers, which capture force, displacement and absorbed energy data during impact events, help engineers understand how damage develops and affects subsequent structural performance.
Such damage can significantly reduce structural performance, even when little evidence is visible on the component surface. Research has shown that carbon fibre coupon specimens can achieve specific energy absorption (SEA) values of around 81 kJ/kg, while full-scale structures may absorb closer to 24 kJ/kg when different geometries trigger alternative failure mechanisms.
By combining advanced materials testing with careful material selection, engineers can make more informed lightweighting decisions. Ultimately, lightweighting succeeds not when there is less material, but when it is fully understood how that material will perform when the unexpected happens.
To discover more about impact testing, download Instron’s latest whitepaper ‘Mastering impact: a modern guide to tensile impact strength testing with drop towers’, here.
www: www.instron.com
https://designsolutionsmag.co.uk/category/materials-in-design-prototyping/
