Evaluation of 3D Printed Soft Robots in Radiation Environments and Comparison With Molded Counterparts

Yirmibeşoğlu, O.D.; Oshiro, Tyler T.; Olson, Gina; Palmer, Camille; Mengüç, Yiğit

doi:10.3389/frobt.2019.00040

Cited by 34 publications

(24 citation statements)

References 49 publications

(74 reference statements)

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“…The vertical prints, where the print direction is parallel with the uniaxial testing setup, fails first compared to print directions that are orthogonal to the axis of loading. We observed similar results in our previous work 50 where we used a faster curing network. We suggest that cross print direction minimizes the voids between laid filaments by knitting trough and crest points, Fig.…”

Section: Resultssupporting

confidence: 89%

Multi-material direct ink writing of photocurable elastomeric foams

et al. 2021

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Developments in additive manufacturing have enabled the fabrication of soft machines that can safely interface with humans, creating new applications in soft robotics, wearable technologies, and haptics. However, designing custom inks for the 3D printing of soft materials with Young’s modulus less than 100 kPa remains a challenge due to highly coupled structure-property-process relationship in polymers. Here, we show a three-stage material chemistry process based on interpenetrating silicone double networks and ammonium bicarbonate particles that decouples the transient behavior during processing from the final properties of the material. Evaporation of ammonium bicarbonate particles at the final stage creates gaseous voids to produce foams with a low effective Young’s modulus in the 25 kPa −90 kPa range. Our photoirradiation-assisted direct ink writing system demonstrates the ability to maintain high resolution while enabling controlled loading of ammonium bicarbonate particles. The resultant multi-material possesses programmed porosity and related properties such as density, stiffness, Shore hardness, and ultimate strength in a monolithic object. Our multi-hardness synthetic hand and self-righting buoyant structure highlight these capabilities.

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Section: Resultssupporting

confidence: 89%

Multi-material direct ink writing of photocurable elastomeric foams

et al. 2021

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“…Soft locomotion robots [ 109 ] are highly desired for applications ( Figure ) that require deploying robots in extreme and harsh dynamic environments where extreme conditions such as elevated temperatures, excessive deformations and pressures, impact forces, tiny and confined spaces (Figure 5A), [ 13 ] and radiations (Figure 5B) [ 110 ] are present. 3D‐printed pneumatically actuated soft robots can be deployed in confined spaces for inspection applications [71a] .…”

Section: D‐printable Soft Pneumatic Actuatorsmentioning

confidence: 99%

A Review of 3D‐Printable Soft Pneumatic Actuators and Sensors: Research Challenges and Opportunities

Tawk

Alici

2021

Advanced Intelligent Systems

102

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The soft robotics field is changing the way people think, build, interact, and most importantly perceive robots. Robots have long been perceived as machines made of metals that their sole purpose is to perform repetitive tasks in isolated environments. Herein, the recently developed soft pneumatic actuators and sensors that are fabricated using additive manufacturing techniques and in which the fluid used for actuation and sensing is mainly or solely air are focused upon. This review presents the soft pneumatic actuators and sensors in terms of their types, materials, fabrication techniques, capabilities, and applications. Also, it offers a discussion on the presented 3D‐printable soft actuators and sensors along with a list of what is needed to develop robust and functional soft actuators and sensors for soft robots and how such robots will evolve in the future. This article is expected to stimulate more interaction between materials scientists and robotic researchers to synthesize soft and functional materials that meet application, function, and user requirements, in a way to implement a top‐down approach to shorten the path between science and application of soft smart materials and their use in establishing functional soft robotic systems.

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“…Materials intelligence: The use of deformable materials could also contribute to inherent compliance, thereby engendering greater self-adaptability and dexterity. Deformable soft-bodied robots are lightweight and flexible while offering high payload capacity and resistance, a combination ideally suited to extreme scenarios, among them certain nuclear applications requiring power and flexibility [12,13].…”

Section: An Illustrative Use Casementioning

confidence: 99%

A Suite of Robotic Solutions for Nuclear Waste Decommissioning

et al. 2021

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Dealing safely with nuclear waste is an imperative for the nuclear industry. Increasingly, robots are being developed to carry out complex tasks such as perceiving, grasping, cutting, and manipulating waste. Radioactive material can be sorted, and either stored safely or disposed of appropriately, entirely through the actions of remotely controlled robots. Radiological characterisation is also critical during the decommissioning of nuclear facilities. It involves the detection and labelling of radiation levels, waste materials, and contaminants, as well as determining other related parameters (e.g., thermal and chemical), with the data visualised as 3D scene models. This paper overviews work by researchers at the QMUL Centre for Advanced Robotics (ARQ), a partner in the UK EPSRC National Centre for Nuclear Robotics (NCNR), a consortium working on the development of radiation-hardened robots fit to handle nuclear waste. Three areas of nuclear-related research are covered here: human–robot interfaces for remote operations, sensor delivery, and intelligent robotic manipulation.

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Evaluation of 3D Printed Soft Robots in Radiation Environments and Comparison With Molded Counterparts

Cited by 34 publications

References 49 publications

Multi-material direct ink writing of photocurable elastomeric foams

Multi-material direct ink writing of photocurable elastomeric foams

A Review of 3D‐Printable Soft Pneumatic Actuators and Sensors: Research Challenges and Opportunities

A Suite of Robotic Solutions for Nuclear Waste Decommissioning

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