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a Corresponding author: [email protected] b levee classes are function of levee height and protected population

River Loire levees hazard studies � CARDigues� model principles and utilization examples on Blois levees

Eduard Durand1,a, Jean Maurin2, Bastien Bridoux2, Arnaud Boulay3 and Arnaud Bontemps1 1CEREMA, Direction Territoriale Normandie-Centre, Laboratoire Régional de Blois, 11 rue Laplace, 41029 Blois Cedex, France 2DREAL Centre-Val de Loire, 5 avenue Buffon, CS96407, 45064 Orléans cedex 2, France 3DDT45, faubourg Bannier, 45000 Orléans, France

Abstract. �� !� �� "��#$�� !��%��&�'��(��(�(��)�� )� � � �� * ��* ��* ��* +��(��),* ��* ��* ��)* ��* ��)��)��-*��*�(�� *��* ��(�� &!&�'��(�� (�(��)�� (��().�� (��)��/��&�%��(��)��(�� )��()��&�'�� $01&22!��/�� )� �� (�� )�� &� � � �� &��

1 Introduction & �� concept

1.1 Context of hazard studies � %�� (�� 0223�� 4�� )�� !�� )� �� )� �� )��&�5�� 6��7�� (� �� )�� .� 5��8�� '�� 092�222� ��(��&��92��(� �� (� � � �)�� (��:22�� &�

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1.2 ��

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�Figure 1. Description of the levee system discretization in representative levee segments (after [10])

DOI: 10.1051/03010 (2016), 6E3S Web of Conferences e3sconf/201

FLOODrisk 2016 - 3rd European Conference on Flood Risk Management 7 0703010

© The Authors, published by EDP Sciences. This is an open access article distributed under the terms of the Creative Commons Attribution License 4.0 (http://creativecommons.org/licenses/by/4.0/).

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�Figure 2. Graphic showing the principle of probabilistic space discretization used in CARDigues (after [6].). For example, the shaded area is affected to the Q500 flood event.

2 Entrance data of CARDigues

2.1 General data

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2.2 Topographic data

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�Figure 3. Characteristic points of a levee profile in CARDigues model (courtesy Durand E.) �

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2.3 Hydraulic data

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2.4 Geotechnical data

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2.5 Structural data and disorders

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2.6 Reinforcement, protection or amelioration data

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2.7 Management data

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3 Breaching processes and failure mechanisms

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3.1. Overflowing��

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�Figure 4. Principle of erosion by overflowing process ([8], Courtesy Y. Deniaud)

3.2 Internal erosion��

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�Figure 5. Examples of internal erosion processes and localizations in the levee or its foundation ([8], Courtesy Y. Deniaud) �

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3.3 slope instability��

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3.4 External erosion��

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3.5 Uplift��

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�Figure 7. Principle of a slope sliding caused by uplift ([8], Courtesy Y. Deniaud)

3.6 Other breaching processes��

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4 Probability calculations

4.1 Hypothesis��

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4.2 Overflowing��

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�Figure 8. Example of overflow breach probability weighting

coefficient function of levee width (after [6])

4.3 Internal erosion��

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�Figure 9. Internal erosion appearance probability function of Bligh ratio (after [6])

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�Figure 10. Table of coefficients applied on Bligh raw ratio (after [6])

4.4 Slope instability��

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�Figure 11. Sliding appearance probability function of factor of safety ranges (after [6])

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�Figure 12. Slope sliding breach probabilities based on internal erosion appearance probabilities over-ranking (after [6])

4.5 External erosion��

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4.6 Uplift��

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5 Example of results on Blois levee system

5.1 Presentation of Blois levee system��

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�Figure 15. Blois levee systems and its 5 protected areas (after [3])

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5.2 Blois left ban levee discretization��

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5.3 Hydraulic data��

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�Figure 16. Blois levee left bank levee profile (black line) and the nine flood level taken into account in CARDigues Blois model (after [3])

5.4 Blois levee cross-section report��

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�Figure 17. Example of GIS visualization of CARDigues probabilities for the Loire flood T1000 on Blois levees (after [3])

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5.5 GIS presentation of Blois results�

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�Figure 18. Example of a levee cross-section report edited with CARDigues tool (after [3])

6 Conclusions and perspectives � [��)� �� )��&�%��(��0221� �� 92� � �� (�� 02;6� �� $01&22!&�M �� (� �� .�#� �� /�� (��#��(��)��Z�#� ��(��)� ��)� �� Z�#��(��)�� Z�#� �� )��

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