Aerospace/Defense

Space flight is one of the most challenging fields for product development and quality control. Every system must be lightweight, strong, and durable to withstand extreme environments, including temperature variations, pressure fluctuations, and high levels of shock and vibration. In this context, piezoelectric materials offer valuable advantages: they can harvest energy from structural vibrations to supply onboard power, support lightweight system design, and enable real-time structural health monitoring to detect early signs of fatigue or damage during missions.

The aviation sector is another area where engineering and product development demands are extremely high, and it also holds a critical share of the global economy. Aircraft, whether commercial planes, helicopters, or unmanned aerial vehicles (UAVs), are highly complex machines that integrate electronics and mechanical components designed to perform reliably over decades of operation. Incorporating piezoelectric materials into these systems offers multiple benefits: they can actively reduce noise and vibration, convert mechanical stresses and oscillations into usable electrical energy, and provide continuous structural health monitoring by detecting early signs of fatigue, corrosion, or cracking.