Powerful, soft combustion actuators for insect-scale robots

Cameron A. Aubin; Ronald H. Heisser; Ofek Peretz; Julia Timko; Jacqueline Lo; E. Farrell Helbling; Sadaf Sobhani; Amir D. Gat; Robert F. Shepherd

doi:10.1126/science.adg5067

Powerful, soft combustion actuators for insect-scale robots

Cameron A. Aubin, Ronald H. Heisser, Ofek Peretz, Julia Timko, Jacqueline Lo, E. Farrell Helbling, Sadaf Sobhani, Amir D. Gat, Robert F. Shepherd

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Insects perform feats of strength and endurance that belie their small stature. Insect-scale robots—although subject to the same scaling laws—demonstrate reduced performance because existing microactuator technologies are driven by low–energy density power sources and produce small forces and/or displacements. The use of high–energy density chemical fuels to power small, soft actuators represents a possible solution. We demonstrate a 325-milligram soft combustion microactuator that ca achieve displacements of 140%, operate at frequencies >100 hertz, and generate forces >9.5 newtons With these actuators, we powered an insect-scale quadrupedal robot, which demonstrated a variety of gait patterns, directional control, and a payload capacity 22 times its body weight. These features enabled locomotion through uneven terrain and over obstacles.

Original language	English
Pages (from-to)	1212-1217
Number of pages	6
Journal	Science
Volume	381
Issue number	6663
DOIs	https://doi.org/10.1126/science.adg5067
State	Published - 15 Sep 2023

All Science Journal Classification (ASJC) codes

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10.1126/science.adg5067

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title = "Powerful, soft combustion actuators for insect-scale robots",

abstract = "Insects perform feats of strength and endurance that belie their small stature. Insect-scale robots—although subject to the same scaling laws—demonstrate reduced performance because existing microactuator technologies are driven by low–energy density power sources and produce small forces and/or displacements. The use of high–energy density chemical fuels to power small, soft actuators represents a possible solution. We demonstrate a 325-milligram soft combustion microactuator that ca achieve displacements of 140\%, operate at frequencies >100 hertz, and generate forces >9.5 newtons With these actuators, we powered an insect-scale quadrupedal robot, which demonstrated a variety of gait patterns, directional control, and a payload capacity 22 times its body weight. These features enabled locomotion through uneven terrain and over obstacles.",

author = "Aubin, \{Cameron A.\} and Heisser, \{Ronald H.\} and Ofek Peretz and Julia Timko and Jacqueline Lo and Helbling, \{E. Farrell\} and Sadaf Sobhani and Gat, \{Amir D.\} and Shepherd, \{Robert F.\}",

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doi = "10.1126/science.adg5067",

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T1 - Powerful, soft combustion actuators for insect-scale robots

AU - Aubin, Cameron A.

AU - Heisser, Ronald H.

AU - Peretz, Ofek

AU - Timko, Julia

AU - Lo, Jacqueline

AU - Helbling, E. Farrell

AU - Sobhani, Sadaf

AU - Gat, Amir D.

AU - Shepherd, Robert F.

PY - 2023/9/15

Y1 - 2023/9/15

N2 - Insects perform feats of strength and endurance that belie their small stature. Insect-scale robots—although subject to the same scaling laws—demonstrate reduced performance because existing microactuator technologies are driven by low–energy density power sources and produce small forces and/or displacements. The use of high–energy density chemical fuels to power small, soft actuators represents a possible solution. We demonstrate a 325-milligram soft combustion microactuator that ca achieve displacements of 140%, operate at frequencies >100 hertz, and generate forces >9.5 newtons With these actuators, we powered an insect-scale quadrupedal robot, which demonstrated a variety of gait patterns, directional control, and a payload capacity 22 times its body weight. These features enabled locomotion through uneven terrain and over obstacles.

AB - Insects perform feats of strength and endurance that belie their small stature. Insect-scale robots—although subject to the same scaling laws—demonstrate reduced performance because existing microactuator technologies are driven by low–energy density power sources and produce small forces and/or displacements. The use of high–energy density chemical fuels to power small, soft actuators represents a possible solution. We demonstrate a 325-milligram soft combustion microactuator that ca achieve displacements of 140%, operate at frequencies >100 hertz, and generate forces >9.5 newtons With these actuators, we powered an insect-scale quadrupedal robot, which demonstrated a variety of gait patterns, directional control, and a payload capacity 22 times its body weight. These features enabled locomotion through uneven terrain and over obstacles.

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DO - 10.1126/science.adg5067

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JO - Science

JF - Science

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ER -

Powerful, soft combustion actuators for insect-scale robots

Abstract

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