Realization of a Contactless Acoustic Levitation Motor via Doublet Mode Control and Autoresonance (1711.00380v1)

Abstract: This paper demonstrates analytically and experimentally an acoustic levitation motor which has the ability to levitate and rotate an object in the air without mechanical contact. To realize such a device two core methods are applied simultaneously; (i) resonance tracking with an Autoresonance feedback loop, (ii) generation of controlled structural traveling waves. The purpose of the first method is to achieve near-field acoustic levitation, which can levitate an object of a few kilograms. In this research, this is accomplished through high amplitude vibration of an aluminum annulus at ultrasonic frequencies (~30kHz). For high efficiency, the annulus is designed to have a very high Q value, and operating even slightly off resonance ceases levitation. Compounding this is the fact that the natural frequency constantly drifts as ambient conditions and loading change. To accommodate such a drift, and produce stable levitation automatically, a resonance tracking feedback loop is employed here. Simultaneously, the purpose of the second method is to achieve propulsion forces on the levitated object by propagating and controlling traveling waves in the aluminum annulus to create a thin layer of rotating air beneath the levitated body. Even though a single vibration mode can produce only standing waves, an axisymmetric structure possesses two modes per natural frequency, and excitation of a doublet mode pair can generate effective travelling waves. The present paper develops the theory behind the use of the Autoresonance feedback method for achieving constant levitation and propagating travelling waves in co- and counter rotating directions. It will be shown that all this can be accomplished with only single sensor. The result is a stable, repeatable and a highly controllable contactless acoustic levitation motor.