MemoSnake

Title

MemoSnake: Design and analysis of a snake-like system with mechanical shape control

 Author

d'Hont, Sander (TU Delft Mechanical, Maritime and Materials Engineering; TU Delft Biomechanical Engineering)

Contributor

Culmone, C. (mentor) ORCID 0000-0003-4194-3788
Sakes, A. (graduation committee) ORCID 0000-0002-4323-884X
van der Wijk, V. (graduation committee) ORCID 0000-0002-7953-4368
Breedveld, P. (graduation committee) ORCID 0000-0002-7235-1657

 Degree granting institution

Delft University of Technology

 Programme

Biomedical Engineering | Medical Instruments and Medical Safety (MIMS)

 Date

2019-11-12

 Abstract

Introduction: When navigating through tight and delicate environments, steerable tools are highly desired. Follow-the-leader locomotion, as in the biological snake, is a solution that is obtained with shape memory control. The often used electric equipment to control the shape makes the current state-of-the-art of snake-like robots too complex. This thesis focused on a snake-like system using mechanical shape control to generate forward motion, to analyze the motion and comment on the expected behavior. Method: A 3D Simulink model was created with friction between the snake-like system and the surroundings as an important relation. A pre-defined sinus wave was passed through the snake-like system to analyze the motion. A low-cost, 3D printed, prototype was developed to validate the friction relation of the model. The prototype contains a belt feature with pre-defined path as shape control system and a snake-like system with four wheeled segments. Different configurations were assessed in the model by changing the wheel axis length, sinus amplitude and sinus frequency. Results: The prototype validated the realistic friction parameters in the model. Given the results of the model, the snake-like system creates forward motion by pushing against the surroundings when a sinus wave is pushed through the system. The wave parameters have a significant influence on displacement. When the configuration of the snake-like system creates more friction with the surroundings, the system is able to push itself further forward and generates more forward displacement. Conclusion:It is demonstrated that forward motion is possible when a snake-like system is connected to a mechanical shape control system. Now, the next step is to investigate random paths, to enable adaptable mechanical shape control being applied.

 Subject

Design
Snake robot
Shape Control
Mechanical

 To reference this document use:

http://resolver.tudelft.nl/uuid:ad3f14c3-0178-4886-aac1-7a04e7875097

 Embargo date

2021-12-31

 Part of collection

Student theses

 Document type

master thesis

 Rights

© 2019 Sander d'Hont
Files
PDF 20191031_MemoSnake_FINAL_ ... rdHont.pdf 15.74 MB
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