Your search keyword '"Kieran Gilday"' showing total 4 results

1. 3D Printable Sensorized Soft Gelatin Hydrogel for Multi-Material Soft Structures

Author

David Hardman, Kieran Gilday, Fumiya Iida, Thomas George Thuruthel, Josie Hughes, Apollo-University Of Cambridge Repository, Hardman, D [0000-0002-5102-0541], Hughes, J [0000-0001-8410-3565], Thuruthel, TG [0000-0003-0571-1672], Gilday, K [0000-0002-8264-1535], Iida, F [0000-0001-9246-7190], and Apollo - University of Cambridge Repository

Subjects

soft robotics, 3D printing, 02 engineering and technology, 01 natural sciences, Gelatin, Strain, Material properties, Soft structure, 3-D printing, Three-dimensional printing, Strain sensors, Soft materials, Hydrogels, Agricultural robots, Carbon black, 021001 nanoscience & nanotechnology, 3D printers, Computer Science Applications, Gelatin hydrogels, Self-healing hydrogels, Three-dimensional displays, Computer Vision and Pattern Recognition, 0210 nano-technology, Robots, Control and Optimization, food.ingredient, Materials science, Fabrication, Biomedical Engineering, Nanotechnology, 010402 general chemistry, Conductive elements, food, Fabrication technique, Artificial Intelligence, Robot sensing systems, Multi materials, Flexibility (engineering), business.industry, Sensors, Mechanical Engineering, Multi material, Control parameters, 0104 chemical sciences, Human-Computer Interaction, Control and Systems Engineering, Machine design, business

Abstract

The ability to 3D print soft materials with integrated strain sensors enables significant flexibility for the design and fabrication of soft robots. Hydrogels provide an interesting alternative to traditional soft robot materials, allowing for more varied fabrication techniques. In this work, we investigate the 3D printing of a gelatin-glycerol hydrogel, where transglutaminase is used to catalyse the crosslinking of the hydrogel such that its material properties can be controlled for 3D printing. By including electron-conductive elements (aqueous carbon black) in the hydrogel we can create highly flexible and linear soft strain sensors. We present a first investigation into adapting a desktop 3D printer and optimizing its control parameters to fabricate sensorized 2D and 3D structures which can undergo >300% strain and show a response to strain which is highly linear and synchronous. To demonstrate the capabilities of this material and fabrication approach, we produce some example 2D and 3D structures and show their sensing capabilities. © 2016 IEEE.

Published

2021

2. Gel-Based Soft Interfaces for Fastener Manipulation in Robotic Agile Assembly

Author

Kieran Gilday, Josie Hughes, and Fumiya Iida

Subjects

business.product_category, Robotic assembly, Computer science, business.industry, Pick and place, Interface (computing), Assembly tasks, Soft interfaces, Mechanical engineering, Robotics, Agile manufacturing, Confined geometries, Fastener, Manufacturing IS, Task (computing), Different sizes, Fluid property, Grippers, Locks (fasteners), Agile manufacturing systems, Robot, SMT placement equipment, business, Agile software development, Holding forces

Abstract

Robotic manufacturing is increasingly moving towards one-off assembly tasks. Agile manufacturing systems must be able to adapt to changing parts and designs. The addition of a soft interface, between a picking tool and a part, can improve the performance and introduce new ways of picking and manipulating parts without increasing complexity. The introduced compliance also assists when mating parts. These soft interfaces can be applied in minimalist pick and place tasks with passive gripping. This work investigates the model behind gel-based soft interfaces, and demonstrates the application for manipulating fasteners in an agile assembly task. The model predicts the limit to the holding force is from a vacuum seal, the actual holding force can be lower due to the fluid properties of the gel in confined geometries. The soft interface is shown to give adaptability for a single tool to pick multiple different sizes of parts. This interface gives success rate > 90% for well aligned cross-head bolts, and much better performance for hex keys and bolts. © 2019 IEEE.

3. Achieving flexible assembly using autonomous robotic systems

Author

Fumiya Iida, Josie Hughes, and Kieran Gilday

Subjects

0209 industrial biotechnology, Robotic assembly, Process (engineering), Computer science, Iterative methods, 020209 energy, Distributed computing, media_common.quotation_subject, 02 engineering and technology, Intelligent robots, Fabrication method, Prefabrication, 020901 industrial engineering & automation, Resource (project management), Limited capacity, Fabrication methods, 0202 electrical engineering, electronic engineering, information engineering, Cost functions, Function (engineering), Agile development, Probability of success, media_common, Flexibility (engineering), Autonomous robotic systems, business.industry, Assembly process, Robotics, Robotic platforms, Grippers, Robot, business, Agile software development, Flexible Assembly

Abstract

Prefabrication of structures is currently used in a limited capacity, due to the lack of flexibility, despite the potential cost and speed advantages. Autonomous flexible reassembly enables structures to be developed which can be continuously and iteratively dis-assembled and re-assembled providing far more flexibility in comparison to single shot pre-fabrication methods. Dis-assembly of structures should be considered when assembling, due to the asymmetry of assembly and dis-assembly processes, to ensure structures can be recycled and re-assembled. This allows for agile development, significantly reducing the time and resource usage during the build process. In this work, a framework for flexible re-assembly is developed and a robotic platform is developed to implement and test this framework with simple Lego bricks. The tradeoffs in terms of time, resource use and probability of success of this new assembly method can be understood by using a cost function to compare to alternative fabrication methods. © 2018 IEEE.

4. Real World Bayesian Optimization Using Robots to Clean Liquid Spills

Author

Josie Hughes, Isobel Voysey, Thomas George Thuruthel, Fumiya Iida, and Kieran Gilday

Subjects

0209 industrial biotechnology, 4608 Human-Centred Computing, Computer science, Iterative methods, Cleaning, Accurate performance, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Task (project management), 020901 industrial engineering & automation, 46 Information and Computing Sciences, Control parameters, Optimized control, Physical experimentations, 0105 earth and related environmental sciences, Bayesian optimization, Robotic systems, Optimal controls, business.industry, Process (computing), Control engineering, Liquids, Robotics, Optimal control, Automation, 4602 Artificial Intelligence, Robot, Automation process, business, Robots

Abstract

Developing robots that can contribute to cleaning could have a significant impact on the lives of many. Cleaning wet liquid spills is a particularly challenging task for a robotic system, and has several high impact applications. This is a hard task to physically model due to the complex interactions between cleaning materials and the surface. As such, to the authors’ knowledge there has been no prior work in this area. A new method for finding optimal control parameters for the cleaning of liquid spills is required by developing a robotic system which iteratively learns to clean through physical experimentation. The robot creates a liquid spill, cleans and assesses performance and uses Bayesian optimization to find the optimal control parameters for a given size of liquid spill. The automation process enabled the experiment to be repeated more than 400 times over 20 h to find the optimal wiping control parameters for many different conditions. We then show that these solutions can be extrapolated for different spill conditions. The optimized control parameters showed reliable and accurate performances, which in some cases, outperformed humans at the same task. © 2020, Springer Nature Switzerland AG.