Design of a high efficiency, large stroke, electromechanical actuator

Autor: Steven R. Hall, Eric F. Prechtl
Rok vydání: 1999
Předmět:
Zdroj: Smart Materials and Structures. 8:13-30
ISSN: 1361-665X
0964-1726
DOI: 10.1088/0964-1726/8/1/002
Popis: Large stroke, electromechanical actuator designs are considered. Special emphasis is placed on actuators designed to power a trailing edge servo-flap system for feedback control of helicopter rotor vibration, acoustics and aerodynamic performance. A survey was conducted comparing the advantages and disadvantages of a number of actuator designs. The major conclusions from this survey indicate that any successful actuator design will utilize a high bandwidth active material, produce large amplification of the active material stroke and incorporate a simple compressive pre-stress mechanism, while remaining efficient in a mass normalized sense. The mass efficiency, defined as the ratio of the specific work performed by the actuator to the specific energy available in the active material element, was used as a metric to rate the actuators considered in the survey. This metric is appropriate in aerospace applications where weight is critical. The most feasible discrete actuators are those where the active material reacts against an inert support frame housing. An upper bound on the mass efficiency of this type of actuator is shown to be a function of the ratio of active material to frame specific modulus. A new high efficiency discrete actuator, the X-frame actuator, is described. A prototype of this actuator was built and tested to confirm the predicted performance. The prototype demonstrates an output energy density of 14.6 ft lb/slug. It has a bandwidth of about 540 Hz when driving a nearly impedance-matched load.
Databáze: OpenAIRE
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