Difference between revisions of "Key technologies"
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− | |[[File:spirit_robot.png|x200px|sans_cadre|]] || || || <big> '''3D Printing of multimaterial polymer structures''' </big> for the design of | + | |[[File:spirit_robot.png|x200px|sans_cadre|]] || || || <big> '''3D Printing of multimaterial polymer structures''' </big> for the design of highly-integrated robotic structures. Picture on the left represents a proof-of-concept developed at ICube-INSA Strasbourg ((c) ICUBE). |
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+ | |[[File:umm_tech.jpg|x200px|sans_cadre|]] || || || <big> '''Hydraulic actuation''' </big> to build compact and efficient actuated tools in the medical environment. | ||
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+ | |[[File:hfu_tech.jpg|x200px|sans_cadre|]] || || || <big> '''Tactile transducer design and manufacturing''' </big> using MEMS technology. | ||
+ | |} | ||
Revision as of 15:14, 10 September 2017
Hydraulic actuation to build compact and efficient actuated tools in the medical environment. |
File:Hfu tech.jpg | Tactile transducer design and manufacturing using MEMS technology. |
Several key technologies are developed thanks to SPIRITS for interventional radiology and more generally for hybrid image-guided surgery:
- 3D printing technologies and their combination. Multimaterial polymer production and metal printing are being considered for manufacturing of robotic technology.
- Hydraulic actuation and compliant mechanisms. Their combination is considered to design efficient robotic structures.
- Instrumented surgical tools for precision increase in robotised tasks.
- Tactile feedback technology for providing new information to the radiologist.