Abstract
Pennate muscle is characterized by muscle fibers that are oriented at a certain angle (pennation angle) relative to the muscle’s line of action and rotation during contraction. This fiber rotation amplifies the shortening velocity of muscle, to match loading conditions without any control system. This unique variable gearing mechanism, which characterized by Architecture Gear Ratio (AGR), is involves complex interaction among three key elements: muscle fibers, connective tissue, and the pennation angle. However, how three elements determine the AGR of muscle-like actuator is still unknown. This study introduces a Himisk actuator that arranges five contractile units at a certain pennation angle in a flexible matrix, the experiment and simulation results demonstrated that the proposed actuator could vary AGR automatically in response to variable loading conditions. Based on this actuator, we present a series of actuators by simulations with the varying pennation angle (P), elastic modulus of the flexible matrix (E), and number of contractile units (N) to analyze their effects on AGR, and their interaction by three-factor analysis of variance. The results demonstrated that P and N effect on the AGR significantly, while E effects on AGR slightly, which supported the idea that the P is the essential factor for the AGR, and N is also an important factor due to the capability of force generation. This provides a better understanding of mechanical behavior and an effective optimizing strategy to muscle-like soft actuator.
Highlights
Skeletal muscle has been deemed a “typical soft actuator” due to their deformable characteristics [1]
The results supported the idea that P is the most important factor for the variable gearing mechanism, which is similar to pennate muscle
We presented three types of actuators by varying the arrangement of contractile units and the flexible matrix, termed PA30-Matrix, PA30-NoMatrix, and
Summary
Skeletal muscle has been deemed a “typical soft actuator” due to their deformable characteristics [1]. The muscle fibers are oriented at an angle relative to the muscle’s line of action and rotation during contraction [2]. The rotation of muscle fibers increases the whole muscle shortening. The displacement or velocity amplification of fiber shortening can be characterized by the muscle’s Architectural Gear Ratio (AGR), which is defined as the ratio of muscle shortening (or muscle velocity) to fiber shortening (or fiber velocity) [3]. When contracting against light loads, the pennate angle of muscle fibers undergo significant changes. When contracting against heavy loads, muscle fibers rotate less and muscle thickness and displacement decreases, which indicates that pennate muscles act as a “automatic transmission system” which is an important mechanical feature of skeletal muscle
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