II) Displacement-amplified piezo actuators with a special gearbox or structural effects to amplify the displacement. An example of an actuator that utilizes a structural deformation effect is the bending transducer (Smart Structures).

The displacement of bending actuators is high and can easily reach 1 mm or more. Acoustic applications of bending transducers are widespread. Telephone capsules for speakers, ultrasonic cleaners, valve actuators, and pump actuators are indispensable in our daily lives. Bending transducers utilize stress-induced deformation and generate useful displacement analogous to bimetallic strips. A bending transducer consists of multiple layers, such as a piezoelectric layer (P) and a passive carrier like a metal sheet (M). The active and passive layers are bonded together with shear rigidity. The most well-known variants are P-M, P-P, and P + -M-P. The +/- indicates the opposite phases of displacement (expansion, contraction). A thin multilayer actuator (low-profile multilayer stack actuator) can also be used as the active piezoelectric layer.

Since the 1990s, an international scene has emerged dedicated to researching smart structures. The focus of research is on the development of smart or multifunctional structures. These structures are more than just load-bearing; they also integrate additional functions such as actuation, sensing, or energy harvesting. Piezoelectrics and shape memory alloys are just two examples of mechanically active materials that can be integrated into fiber-reinforced plastics. When these material components are activated, targeted stress-induced structural deformations can be triggered. Smart structures have already been successfully demonstrated for active vibration damping and aerodynamic control. Their gap-free, smooth shape makes them highly attractive for aerodynamic control elements.