Etude du comportement granulaire en transport par charriage basée sur un modèle Eulérien-Lagrangien / Investigation of granular behavior in bedload transport using an Eulerian-Lagrangian model

Maurin, Raphaël

11 December 2015

Turbulent bedload transport represents the main contribution to the riverbed morphological evolution, and associates the non-trivial collective granular behavior with a turbulent fluid flow. Therefore, its description is both a scientific challenge and a societal issue. The present numerical approach focuses on the granular phase characterization, and considers idealized steady uniform bedload transport, with monodisperse spherical beads and a unidirectional fluid flow. This simplified configuration allows to study the underlying physical mechanisms.A minimal coupled numerical model is proposed, associating a three dimensional discrete element method with a one-dimensional volume-averaged fluid momentum balance resolution. The model is compared with classical experimental results of dimensionless sediment transport rate as a function of the Shields number. The comparison is extended to granular depth profiles of solid volume fraction, solid velocity and sediment transport rate density in quasi-2D bedload transport configurations. Parameter sensitivity analysis evidenced the importance of the fluid-particle phase coupling, and showed a robust agreement of the model with the experiments. The validated model is further used to analyze the granular depth structure in bedload transport. Varying the channel inclination angle and the specific density, it is shown that the classical Shields number and dimensionless sediment transport rate formulations do not take appropriately into account the effects of these two parameters. Analyzing the solid depth profiles and the continuous two-phase flow equations, the neglected fluid flow inside the granular bed is identified as the missing contribution. Its importance is enhanced near the transition to debris flow. A rescaling of the Shields number is proposed and is shown to make all the data collapse onto a master curve when considering the dimensionless sediment transport rate as a function of the modified Shields number. Lastly, the bedload transport granular rheology is characterized by computing locally the stress tensor as a function of the depth. The lowermost part is shown to follow a creeping regime and exhibits signature of non-local effects. The dense granular flow on the top of it, is well described by the mu(I) rheology and is observed to persist up to unexpectedly high inertial numbers. It is characterized by the co-existence of frictional and collisional contributions. The transition from dense to dilute granular flow is controlled by the Shields number, the slope and the specific density. Saltation is observed in the uppermost granular layer. These findings improve the understanding of bedload transport granular mechanisms and challenge the existing granular rheologies. / Turbulent bedload transport represents the main contribution to the riverbed morphological evolution, and associates the non-trivial collective granular behavior with a turbulent fluid flow. Therefore, its description is both a scientific challenge and a societal issue. The present numerical approach focuses on the granular phase characterization, and considers idealized steady uniform bedload transport, with monodisperse spherical beads and a unidirectional fluid flow. This simplified configuration allows to study the underlying physical mechanisms.A minimal coupled numerical model is proposed, associating a three dimensional discrete element method with a one-dimensional volume-averaged fluid momentum balance resolution. The model is compared with classical experimental results of dimensionless sediment transport rate as a function of the Shields number. The comparison is extended to granular depth profiles of solid volume fraction, solid velocity and sediment transport rate density in quasi-2D bedload transport configurations. Parameter sensitivity analysis evidenced the importance of the fluid-particle phase coupling, and showed a robust agreement of the model with the experiments. The validated model is further used to analyze the granular depth structure in bedload transport. Varying the channel inclination angle and the specific density, it is shown that the classical Shields number and dimensionless sediment transport rate formulations do not take appropriately into account the effects of these two parameters. Analyzing the solid depth profiles and the continuous two-phase flow equations, the neglected fluid flow inside the granular bed is identified as the missing contribution. Its importance is enhanced near the transition to debris flow. A rescaling of the Shields number is proposed and is shown to make all the data collapse onto a master curve when considering the dimensionless sediment transport rate as a function of the modified Shields number. Lastly, the bedload transport granular rheology is characterized by computing locally the stress tensor as a function of the depth. The lowermost part is shown to follow a creeping regime and exhibits signature of non-local effects. The dense granular flow on the top of it, is well described by the mu(I) rheology and is observed to persist up to unexpectedly high inertial numbers. It is characterized by the co-existence of frictional and collisional contributions. The transition from dense to dilute granular flow is controlled by the Shields number, the slope and the specific density. Saltation is observed in the uppermost granular layer. These findings improve the understanding of bedload transport granular mechanisms and challenge the existing granular rheologies.

Transport sédimentaire

Charriage

Méthode par éléments discret

Couplage fluide-Grain

Rhéologie granulaire

Sediment transport

Bedload

Discrete element method

Fluid-Grain coupling

Granular depth structure

Granular rheology

550

Variationen av övningsuppgifter i matematikläromedel på gymnasiet / Variation of Exercises in Swedish Upper Secondary School Mathematics Textbooks

Roxling, Vilhelm

January 2024

I det här arbetet har variationen av närliggande övningsuppgifter i svenska matematikläromedel för gymnasiet studerats, genom att framförallt betrakta förekomsten av inflätad övning och dess motsats, blockövning, men även SSDD-uppgifter. Detta gjordes genom att kategorisera uppgifternas yt- och djupstrukturer och definiera inflätad övning och SSDD-uppgifter utifrån likhet och olikhet av dessa. En diskussion av vilka konsekvenser den observerade variationen kan ha för lärande har också gjorts, genom teoretiska perspektiv av relevans för inflätad övning, vilka främst varit distribuerat lärande, kontrastering och motivation. Resultaten visar att blockövning dominerar med 65 % av lektionsuppgifterna, mot 14 % inflätad övning, men att denna uppdelning varierar mycket. Inflätad övning är koncentrerad till de blandade övningarna i slutet på varje kapitel, och till ett fåtal avsnitt, medan nästan hälften av avsnitten inte har några inflätade övningar. SSDD-uppgifter finns nästan inte alls. Konsekvenserna är främst ett kortsiktigt lärande som inte ger eleverna tillräckligt med övning i att välja strategi när de ska lösa uppgifter, jämfört med om en högre grad av inflätad övning hade använts.

mathematics textbooks

interleaved mathematics practice

SSDD-problems

surface features

depth structure

distributed practice

matematikläromedel

inflätat lärande

SSDD-uppgifter

ystruktur

djupstruktur

distribuerat lärande

Didactics

Didaktik