Shipboard design and fabrication of custom 3D-printed soft robotic manipulators for the investigation of delicate deep-sea organisms

Vogt, DM; Becker, KP; Phillips, BT; Graule, MA; Rotjan, RD; Shank, TM; Cordes, EE; Wood, RJ; Gruber, DF

Item

Shipboard design and fabrication of custom 3D-printed soft robotic manipulators for the investigation of delicate deep-sea organisms

Vogt, DM
;
Becker, KP
;
Phillips, BT
;
Graule, MA
;
Rotjan, RD
;
Shank, TM
;
Cordes, EE
;
Wood, RJ
;
Gruber, DF

Genre

Journal Article

Date

2018-08-01

DOI

10.1371/journal.pone.0200386

Abstract

© 2018 Vogt et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Soft robotics is an emerging technology that has shown considerable promise in deep-sea marine biological applications. It is particularly useful in facilitating delicate interactions with fragile marine organisms. This study describes the shipboard design, 3D printing and integration of custom soft robotic manipulators for investigating and interacting with deep-sea organisms. Soft robotics manipulators were tested down to 2224m via a Remotely-Operated Vehicle (ROV) in the Phoenix Islands Protected Area (PIPA) and facilitated the study of a diverse suite of soft-bodied and fragile marine life. Instantaneous feedback from the ROV pilots and biologists allowed for rapid re-design, such as adding “fingernails”, and re-fabrication of soft manipulators at sea. These were then used to successfully grasp fragile deep-sea animals, such as goniasterids and holothurians, which have historically been difficult to collect undamaged via rigid mechanical arms and suction samplers. As scientific expeditions to remote parts of the world are costly and lengthy to plan, on-the-fly soft robot actuator printing offers a real-time solution to better understand and interact with delicate deep-sea environments, soft-bodied, brittle, and otherwise fragile organisms. This also offers a less invasive means of interacting with slow-growing deep marine organisms, some of which can be up to 18,000 years old.

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Shipboard design and fabrication of custom 3D-printed soft robotic manipulators for the investigation of delicate deep-sea organisms

Vogt, DM
;
Becker, KP
;
Phillips, BT
;
Graule, MA
;
Rotjan, RD
;
Shank, TM
;
Cordes, EE
;
Wood, RJ
;
Gruber, DF

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Shipboard design and fabrication of custom 3D-printed soft robotic manipulators for the investigation of delicate deep-sea organisms

Vogt, DM ; Becker, KP ; Phillips, BT ; Graule, MA ; Rotjan, RD ; Shank, TM ; Cordes, EE ; Wood, RJ ; Gruber, DF

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Vogt, DM
;
Becker, KP
;
Phillips, BT
;
Graule, MA
;
Rotjan, RD
;
Shank, TM
;
Cordes, EE
;
Wood, RJ
;
Gruber, DF