论文信息 - Increasing the Mechanical Work Output of an Active Material Using a Nonlinear Motion Transmission Mechanism

Increasing the Mechanical Work Output of an Active Material Using a Nonlinear Motion Transmission Mechanism

A nonlinear motion transmission mechanism for improving the mechanical work output of an active material drive element is presented. This improvement is achieved by addressing the typical mismatch between the characteristics of a driven load, such as a constant force or spring load, and the active material’s force-displacement behavior; this behavior is described, at a constant drive level, by a linear decrease in the possible force with increasing displacement. The motion transmission mechanism consists of a simple linkage that couples the active material to the load. As the active material does work on the load, the linkage changes the mechanical advantage or leverage of the active material with respect to the load, thereby tailoring the load to best exploit the active material’s force-displacement behavior. A kinematic model is used to predict the maximum quasi-static mechanical work output that can be obtained. Optimization of the model geometry results in a transmission with a theoretical work enhancement of 37% for a constant load, and a theoretical work enhancement that approaches 100% for a spring load. The possibility of work enhancement is verified in an experiment that demonstrates a work output improvement of 27% for the constant load case.

[1] Diann Brei,et al. Modeling and Study of the Quasi-Static Behavior of Piezoceramic Telescopic Actuation Architectures , 1999 .

[2] Gary H. Koopmann,et al. Modeling and Design Optimization of a Bimorph-Driven Rotary Motor , 2003 .

[3] Gary H. Koopmann,et al. Resonant bimorph-driven high-torque piezoelectric rotary motor , 2001, SPIE Smart Structures and Materials + Nondestructive Evaluation and Health Monitoring.

[4] Nesbitt W. Hagood,et al. Actuation efficiency in piezoelectrically driven linear and nonlinear systems , 1999, Smart Structures.

[5] Gih-Keong Lau,et al. Systematic Design of Displacement-Amplifying Mechanisms for Piezoelectric Stacked Actuators Using Topology Optimization , 2000 .

[6] T. Hemsel,et al. Survey of the present state of the art of piezoelectric linear motors , 2000, Ultrasonics.

[7] S. Hall,et al. Design of a high efficiency, large stroke, electromechanical actuator , 1999 .

[8] I. Chopra,et al. Design of piezostack-driven trailing-edge flap actuator for helicopter rotors , 2001 .

[9] C. Liang,et al. Coupled Electro-Mechanical Analysis of Adaptive Material Systems-Determination of the Actuator Power Consumption and System Energy Transfer , 1997 .

[10] George A. Lesieutre,et al. Can a Coupling Coefficient of a Piezoelectric Device be Higher Than Those of Its Active Material? , 1997, Smart Structures.