LEGO bricks have long been celebrated for their durability, modularity, and vibrant design. Beyond their role in childhood play, these tiny yet mighty blocks offer intriguing insights into material science. In a recent experiment by the Hydraulic Press Channel, a slab of 10,000 LEGO bricks was put to the ultimate test—a faceoff with a 300-ton hydraulic press.

This experiment highlights not only the remarkable strength of LEGO bricks but also the resilience of their primary material: acrylonitrile butadiene styrene (ABS). ABS is a thermoplastic polymer prized for its rigidity, toughness, and impact resistance. These qualities make it a go-to material for many applications, including automotive components, consumer products, and industrial parts.

Material Insights: The Strength of ABS Plastic
A single LEGO brick can withstand over 4,240 newtons of force, equivalent to nearly 1,000 pounds of pressure before it begins to break. In practical terms, this means you could stack an estimated 375,000 LEGO bricks before the bottom one fails. This exceptional strength, coupled with the material’s lightweight properties, is a testament to the engineering behind ABS plastic.

While ABS is durable and versatile, it is not inherently sustainable. Being petroleum-based, it poses challenges for recyclability and environmental impact. However, initiatives within the design and manufacturing industries are exploring biobased alternatives to ABS, as well as closed-loop recycling systems to minimize waste. For architects, product designers, and engineers, experiments like this highlight the importance of durability and the potential for integrating sustainable material solutions into structural or modular designs.

The Experiment: 10,000 Bricks vs. Hydraulic Force
To put LEGO’s durability to the test, the Hydraulic Press Channel team constructed a slab of 10,000 interconnected bricks, matching the hydraulic press plate’s size. While smaller piles of bricks showed limited results, the full slab demonstrated a more dramatic display of resilience. Under immense pressure, the slab deformed slowly rather than shattering instantly, with some blocks ejecting from the cube due to the sheer force.

Interestingly, many bricks survived the compression, further showcasing their structural integrity. This resilience opens the door to considering ABS-based materials for applications requiring modular, impact-resistant components—though with an eye on the environmental footprint.

Source: MY Modern Met
Photo: Hydraulic Press Channel