Dynamic fragmentation of ice spheres: Two specific fracture patterns

Uenishi, Koji; Yoshida, Tomoya; Ionescu, Ioan R.; Suzuki, Kojiro

doi:10.1016/j.prostr.2018.12.111

Cited by 5 publications

(6 citation statements)

References 9 publications

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“…In this case, surface waves with relatively short wavelengths are not generated and the larger-scale ‘orange segments’-type fracture pattern may be more easily found. Together with figures 1 and 6, these numerical speculations may suggest a possible influence of the initial wavelengths relative to the size of the sphere, c P T / a , on ensuing three-dimensional wave evolution and the initiation and extension of dynamic fracture inside the sphere, but this does not necessarily mean that the role played by the crystalline structure of ice, residual stress, if any, etc., is fully negligible [11]. However, additional experiments using a pressure sensor of effective radius 6.35 mm in combination with laser displacement sensors suggest that the rise time, here, the time needed to reach a certain pressure, approximately 40 kPa, upon impact, is generally shorter when the fracture is the ‘orange segments’-type.…”

Section: Discussion: Waves and Fracturementioning

confidence: 99%

“…These experimental observations are consistent with our numerical speculations of different wave patterns in figure 7. Also, more rigorous discontinuous Galerkin (DG) simulations, which are based on the second-order numerical scheme and include the dynamic unilateral contact between the sphere and a rigid plate where the normal stress is proportional to the penetration depth through a compliance coefficient 1.7 × 10 4 GPa m −1 , indicate that for the impact speed of 4.67 m s −1 having experimentally given the ‘top’-type fracture pattern, the maximum shear stress τ max (Tresca criterion) seems to be a promising fracture criterion, while for a larger impact speed of 5.83 m s −1 having induced the ‘orange segments’-type fracture pattern, a different criterion, the maximum principal stress σ 1 or Rankine criterion, looks plausible [11]. However, it is hard to directly and visually trace the involved dynamics by looking at these physical quantities τ max and σ 1 only.…”

Section: Discussion: Waves and Fracturementioning

confidence: 99%

“…Figure 6 shows the two representative fracture patterns repeatedly recognized: (i) only the sections in the proximity of the free surface of the lower hemisphere are fragmented upon collision and the relatively large top-shaped part remains unbroken (here named ‘top’-type fracture pattern; figure 6 a ); and (ii) the sphere is divided mainly into several large segments of similar size like segments of oranges (named ‘orange segments’-type fracture pattern; figure 6 b and also figure 1). Further laboratory experiments using another different receptacle that makes a more single crystal-like transparent ice sphere of radius 30 mm do support the presence of the two specific, plain fracture patterns, even without the pre-existence of apparent material inhomogeneities like air bubbles and planes of weakness in ice spheres [2,11]. Now the question is how to analytically or numerically express the dynamics of fracture, particularly the mechanical difference between the two patterns.…”

Section: Fracture Dynamically Developing From the Edge Of A Spherementioning

confidence: 99%

“…However, the sphere in ( a ) is fragmented only near the lower surface and the most part remains unbroken (‘top’-type fracture pattern) while that in ( b ) is split into several larger segments of comparable size (‘orange segments’-type fracture pattern). In each sequence, the time elapsed after the leftmost photograph taken at the beginning of collision is 40, 500, 2000 and 8000 μs (after [11]). The estimated P and S wave speeds of the ice spheres are c P ≈ 4000 m s −1 and c S ≈ 2000 m s −1 , and, for instance, the time required for an S wave to propagate the distance of the diameter, 50 mm, is about 25 µs.…”

Section: Fracture Dynamically Developing From the Edge Of A Spherementioning

confidence: 99%

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Unexpected, mystifying but simple three-dimensional dynamic fracture phenomena

Uenishi

2021

Phil. Trans. R. Soc. A.

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This contribution addresses what can be learnt from our recent experimental observations of dynamic fracture development in brittle solid materials with real three-dimensional configurations. It is pointed out that the three-dimensional dynamic behaviour of (quasi-)brittle solids is essentially different not only from the one-dimensional dynamic one but also from the three-dimensional static one. The experimental observations include those of cylindrical concrete columns pressurized by deflagration at the centre and ice spheres subjected to dynamic impact at the bottom. Surprisingly, plain fracture patterns can be found through these experiments, but it does not seem simple to describe or predict the involved physical process by conventional analytical treatment or numerical simulations. Indeed, our understanding of mechanical details of actual three-dimensional fracture is still limited, especially in dynamic cases where the length scale of fracture and relevant waves is of the order of the size of solids under consideration. Although a more sophisticated physical interpretation including the dynamic interaction of waves in a relatively high-frequency range is required, the discussed dynamics of three-dimensional fracture development will assist in generating precisely controlled dynamic fracture networks that can be used for practical purposes of dismantling solid structural components and mitigating risks of catastrophic failures. This article is part of the theme issue ‘Fracture dynamics of solid materials: from particles to the globe’.

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Section: Discussion: Waves and Fracturementioning

confidence: 99%

Section: Discussion: Waves and Fracturementioning

confidence: 99%

Section: Fracture Dynamically Developing From the Edge Of A Spherementioning

confidence: 99%

Section: Fracture Dynamically Developing From the Edge Of A Spherementioning

confidence: 99%

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Unexpected, mystifying but simple three-dimensional dynamic fracture phenomena

Uenishi

2021

Phil. Trans. R. Soc. A.

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“…Whereas difference energy impact _ by to geometry part of matter, originate from point energy center impact direct; then the impact of the energy propagates through throughout the material as concussion dynamic fragmentation pattern [28][29][30][31][32][33][34]. By because that's the principal pulverization is the process of material fragmentation, where sample move and stomp self to wall base when the material have kinetic energy.…”

Section: Introductionmentioning

confidence: 99%

Impact of Comminution Kinetic Energy: First Mathematical Modeling of Fragmentation Dynamic Fractures Per Millimetre of Coal

Nasution

Mursito

Astuti

et al. 2023

Preprint

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The various aspects of coal, including its chemical composition, properties, and environmental impacts. The recent research focused on developing new technologies and processes to improve the efficiency and effectiveness of coal comminution, with a particular focus on the use of kinetic energy impact application of coal comminution with linear momentum. We explored the potential benefits of this approach, as well as ongoing research aimed at optimizing the comminution process and improving our understanding of the physics of coal comminution. Ultimately, the goal of this research is to reduce energy consumption and environmental impact associated with coal mining and use. From calculation on comminution of coal samples 10 mm long, 1 mm thick and 1 mm wide using linear momentum kinetic impact energy were carried out to produce coal between 100 mm and 1 mm in size. The main parameters of the process are the configuration of the impact surface of the runway wall, volume, mass and initial size of the sample, as well as the impact distance to the runway. The results of the analysis produce 55 process equations with models per millimetre scale; starting from the equation. The value of the kinetic energy of the fragmentation impact is increasing small if the distribution of energy has an increasing impact Far from static center impact; following with bigger size fragment. With doubling the value of the distribution of impact kinetic energy per millimetre; uniformity size fragment between 100mm to 1mm reached. This first mathematical model is expressed as a comminution dynamic fragmentation linear pattern per millimetre.

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