2 Citations (Scopus)
184 Downloads (Pure)

Abstract

The high potential impact of soft robotics is hampered by a lack of actuators that combine high-force, high-work and high-power capabilities, limiting application in real-world problems. Typically, soft actuators are tuned to an application by gearing - for example, trading power for strain. An example of a recently developed soft-actuator which exploits such gearing is the dielectrophoretic liquid zipping (DLZ) actuator. DLZs can produce large strains (>99%) and power densities comparable to biological muscles, but cannot achieve both in a single actuator. In this work, we introduce a muscle-mimetic DLZ ratcheting actuator (DLZ-R) that allows multiple DLZ-R heads to operate in parallel, thereby increasing force output without sacrificing stroke or power. We first characterise the effect of geometry on the performance of a 1-head DLZ-R, before demonstrating that the force, work, and power output of the DLZ-R scale linearly with the number of active DLZ heads. Next, we investigate the relationship between driving frequency and power output. Finally, we demonstrate a 12-head DLZ ratchet. We believe the DLZ-R represents a step towards soft actuators that can provide both high-work and high-power and the widespread use of soft technologies.
Original languageEnglish
Pages (from-to)3938-3944
Number of pages7
JournalIEEE Robotics and Automation Letters
Volume7
Issue number2
Early online date7 Feb 2022
DOIs
Publication statusPublished - 1 Apr 2022

Keywords

  • Actuators
  • Laser beams
  • Force
  • Dielectrophoresis
  • Electrostatics
  • Liquids
  • Structural beams

Fingerprint

Dive into the research topics of 'Design and Characterisation of a Muscle-mimetic Dielectrophoretic Ratcheting Actuator'. Together they form a unique fingerprint.

Cite this