Historical evolution and new trends for soil-intruder interaction modeling

Pirrone, Serena R. M.; Dottore, Emanuela Del; Mazzolai, Barbara

doi:10.1088/1748-3190/ac99c4

Cited by 4 publications

(2 citation statements)

References 92 publications

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“…This paper aims to better understand the role of plantinspired radial growth in penetration performances by investigating the effects over different soil conditions (varying density and inter-particle cementation) and proposes a three-dimensional (3D) numerical model for a plant rootlike simulant penetrating soil. A 3D discrete element model (DEM) [13,31] was developed to simulate the apical growth into cohesionless granular and cemented media. In the former case, both dense and loose media are investigated.…”

Section: Introductionmentioning

confidence: 99%

Investigations of bioinspired soil penetration strategies via a numerical model: Does radial expansion improve soil intruder performances?

Pirrone,

Del Dottore,

Sibille

et al. 2024

Acta Geotech.

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This paper investigates the performances shown during underground exploration by a plant root-inspired soil intruder. Plant roots are efficient soil explorers, moving by growing at their apical extremities and morphing their bodies in response to mechanical constraints. A three-dimensional (3D) discrete element model (DEM) was developed to mimic selected features of plant roots and verify their usefulness in soil penetration operations. Specifically, the model is used to simulate the penetration of an intruder that grows at the tip into both cohesionless granular and cemented soils. In the former case, dense and loose granular media are considered. The model is adopted to compare penetration performances with purely axial growth and a combination of radial and axial growths. Radial growth is hypothesized to be adopted in roots to facilitate soil penetration. Results from our model suggest that implementing a radial growth preliminary to an axial growth is more advantageous in cohesionless dense granular soil, reducing the soil resistance experienced by the intruder for deeper penetration after radial enlargement. When the penetration occurs in cemented soil, the radial expansion results advantageous over a lower penetration depth, and its beneficial effect drops with increasing inter-particle contact adhesion values. The proposed 3D DEM numerical model provides a methodology for evaluating the intruder penetration efficiency and supports the design of artificial robotic systems for the autonomous exploration of soil by allowing the selection of the most performant penetration strategies for their artificial implementation.

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Section: Introductionmentioning

confidence: 99%

Investigations of bioinspired soil penetration strategies via a numerical model: Does radial expansion improve soil intruder performances?

Pirrone,

Del Dottore,

Sibille

et al. 2024

Acta Geotech.

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“…This is a long-lasting problem that has been analyzed both experimentally, by considering penetrometers [26], [27], natural [15], [28], [29] and/or robotic roots [15], [16], and through mathematical models [14], [30]. Modeling soil penetration is highly challenging [31]. Several complex processes occur during soil interactions, such as the separation of soil layers, the appearance of cracks, and the flow of soil particles.…”

Section: Introductionmentioning

confidence: 99%

A Methodology to Investigate the Design Requirements of Plant Root-Inspired Robots for Soil Exploration

Pirrone

Dottore

Sibille

et al. 2023

IEEE Robot. Autom. Lett.

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This paper proposes a methodology to investigate soil penetration requirements to extract specifications for designing robotic soil excavators and explorers. To this purpose, a three-dimensional (3-D) numerical model based on the Discrete Element Method (DEM) is proposed to simulate an intruder penetration and its interaction with the environment. In this study, the penetration process was analyzed as a function of the intruder diameter to median particle size ratio (Droot/D50), highlighting important differences for small and big ratios conditions (i.e., Droot/D50<<1 and Droot/D50>>1). In particular, the soil resistance force that autonomous penetration systems must overcome when moving into cohesionless granular soil was estimated based on the intruder size (diameter) and the median granularity (D50). This study estimates how the penetration requirements vary according to different penetration strategies. Specifically, a plant root-inspired axial movement emulating the growth from the tip adopted by plants is compared with a penetration obtained by pushing a system from the top. Our findings provide important guidelines about the design requirements (system size, penetration strategy, and actuation power) for artificial penetrating systems, like autonomous explorative robots, to improve their performances during underground exploration.

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Modeling the impact of terrain surface deformation on drag force using discrete element method and empirical formulation

Jiaxin,

Tian,

Wang

et al. 2024

Applied Mathematical Modelling

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Historical evolution and new trends for soil-intruder interaction modeling

Cited by 4 publications

References 92 publications

Investigations of bioinspired soil penetration strategies via a numerical model: Does radial expansion improve soil intruder performances?

Investigations of bioinspired soil penetration strategies via a numerical model: Does radial expansion improve soil intruder performances?

A Methodology to Investigate the Design Requirements of Plant Root-Inspired Robots for Soil Exploration

Modeling the impact of terrain surface deformation on drag force using discrete element method and empirical formulation

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