Dynamics of Elastic Beams with Embedded Fluid-Filled Parallel-Channel Networks

Matia, Yoav; Gat, Amir D.

doi:10.1089/soro.2014.0020

Cited by 37 publications

(19 citation statements)

References 14 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We consider branching as a relevant parameter because already today many industrial technologies are seeking structures that may result in more robust and efficient production from fracture networks (Jinzhou et al 2018). We further note that the model presented here may be relevant to other situations that involve the deformation, relaxation or depressurisation of rigid or compliant materials such as, for example, in common microfluidic devices (Weibel et al 2007) or soft robotics (Matia & Gat 2015).…”

Section: Introductionmentioning

confidence: 99%

Backflow from a model fracture network: an asymptotic investigation

et al. 2019

View full text Add to dashboard Cite

We develop a model for predicting the flow resulting from the relaxation of pre-strained, fluid-filled, elastic network structures. This model may be useful for understanding relaxation processes in various systems, e.g. deformable microfluidic systems or by-products from hydraulic fracturing operations. The analysis is aimed at elucidating features that may provide insight on the rate of fluid drainage from fracturing operations. The model structure is a bifurcating network made of fractures with uniform length and elastic modulus, which allows for general self-similar branching and variation in fracture length and rigidity between fractures along the flow path. A late-time $t^{-1/3}$ power law is attained and the physical behaviour can be classified into four distinct regimes that describe the late-time dynamics based on the location of the bulk of the fluid volume (which shifts away from the outlet as branching is increased) and pressure drop (which shifts away from the outlet as rigidity is increased upstream) along the network. We develop asymptotic solutions for each of the regimes, predicting the late-time flux and evolution of the pressure distribution. The effects of the various parameters on the outlet flux and the network’s drainage efficiency are investigated and show that added branching and a decrease in rigidity upstream tend to increase drainage time.

show abstract

Section: Introductionmentioning

confidence: 99%

Backflow from a model fracture network: an asymptotic investigation

et al. 2019

View full text Add to dashboard Cite

show abstract

“…The accuracy of the model is typically improved when material parameters are first experimentally measured [51] either uniaxially [19,24,35,52,53] or biaxially [50]. Further, few dynamic FEM models are reported in literature [52,54], and in general complex soft robots topologies remain challenging to model. Lastly, the concept of evolutionary optimisation algorithms has also been implemented to shape actuators.…”

Section: Finite Element Methodsmentioning

confidence: 99%

Elastic Inflatable Actuators for Soft Robotic Applications

et al. 2017

View full text Add to dashboard Cite

The 20th century's robotic systems have been made from stiff materials, and much of the developments have pursued ever more accurate and dynamic robots, which thrive in industrial automation, and will probably continue to do so for decades to come. However, the 21st century's robotic legacy may very well become that of soft robots. This emerging domain is characterized by continuous soft structures that simultaneously fulfill the role of robotic link and actuator, where prime focus is on design and fabrication of robotic hardware instead of software control. These robots are anticipated to take a prominent role in delicate tasks where classic robots fail, such as in minimally invasive surgery, active prosthetics, and automation tasks involving delicate irregular objects. Central to the development of these robots is the fabrication of soft actuators. This article reviews a particularly attractive type of soft actuators that are driven by pressurized fluids. These actuators have recently gained traction on the one hand due to the technology push from better simulation tools and new manufacturing technologies, and on the other hand by a market pull from applications. This paper provides an overview of the different advanced soft actuator configurations, their design, fabrication, and applications.

show abstract

“…We now turn to investigate by experiments the results achieved from the theoretical parametric study of the lumped model in Section II. As previously introduced, our soft robot consists of a rectangular elastic beam with two embedded slender fluidic networks, which were studied extensively in our previous works [22], [23], [45]. The robot is fabricated by casting Dragon Skin TM silicone rubber over two serpentine cores 3D-printed from PVA, which is water-soluble.…”

Section: Methodsmentioning

confidence: 99%

Understanding Inchworm Crawling for Soft-Robotics

Gamus

Salem

Gat

et al. 2020

IEEE Robot. Autom. Lett.

Self Cite

View full text Add to dashboard Cite

Crawling is a common locomotion mechanism in soft robots and nonskeletal animals. In this work we propose modeling soft-robotic legged locomotion by approximating it with an equivalent articulated robot with elastic joints. For concreteness we study the inchworm crawling of our soft robot with two bending actuators, via an articulated three-link model. The solution of statically indeterminate systems with stick-slip contact transitions requires for a novel hybrid-quasistatic analysis. Then, we utilize our analysis to investigate the influence of phase-shifted harmonic inputs on performance of crawling gaits, including sensitivity analysis to friction uncertainties and energetic cost of transport. We achieve optimal values of gait parameters. Finally, we fabricate and test a fluid-driven soft robot. The experiments display good agreement with the theoretical analysis, proving that our simple model correctly captures and explains the fundamental principles of inchworm crawling and can be applied to other softrobotic legged robots.

show abstract

Dynamics of Elastic Beams with Embedded Fluid-Filled Parallel-Channel Networks

Cited by 37 publications

References 14 publications

Backflow from a model fracture network: an asymptotic investigation

Backflow from a model fracture network: an asymptotic investigation

Elastic Inflatable Actuators for Soft Robotic Applications

Understanding Inchworm Crawling for Soft-Robotics

Contact Info

Product

Resources

About