![Програма за ТГС по ИПП България – Сърбия
5. HYDROLOGY
5.1. DETERMINATION OF THE MAXIMUM RUN-OFF
Statistical methods
The statistical methods are applicable for determination of the maximum run-off in
basins with built hydrometric network and an area greater than 1000 km. The
statistical methods are applied in both countries.
Models „rainfall – run-off”
Figure 6 Model „Rainfall – run-off”
Method for regionalization of the maximum run-off
Eight factors and characteristics of drainage basins and river systems that are
essential for the formation of maximum flow are set out in LUBW, 2007:
• area of the catchment AEo [km2]
• urbanized territory S [%]
• afforestation W [%]
EUROPEAN UNION
Bulgaria – Serbia IPA Cross-border Programme
“Assessment of flood risk – a base for sustainable development in upper part of Nishava
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![Програма за ТГС по ИПП България – Сърбия
• average slope Ig [%]
• river length L [km] along the main rivers of the watershed to the confluence
• river length LC [km] from the center of gravity of the catchment to its estuary;
• average annual rainfall in the catchment hNG [mm]
• landscape factor LF [-]
GEODESY
DIGITAL TERRAIN MODEL
A variety of sources can be used to create a terrain elevation model: topographic
maps, satellite images, orthophotos, surveys of the river flow, LIDAR. The described
sources are characterized by different accuracy of the topographical information.
Therefore, the combined use of these sources is recommended to obtain a digital
terrain model with sufficient accuracy.
Figure 7 Geodesic measurements /shooting of cross-sections/
EUROPEAN UNION
Bulgaria – Serbia IPA Cross-border Programme
“Assessment of flood risk – a base for sustainable development in upper part of Nishava
catchment” Page 8](https://image.slidesharecdn.com/metodikaenfinal-120830102552-phpapp02/85/Metodika-en-final-8-320.jpg)
![Програма за ТГС по ИПП България – Сърбия
легенда:
заливни дълбочини за висока вълна с
период на повторение 100 години [см]
залети площи
площи със свободен борд < 30 см
степен на застрашеност на сгради:
незастрашени сгради
потенциално застрашени сгради
Figure 19 Borders of inundation and calcualted depths of floods during high wave
with repetition period 100 years, respectively 1% security.
легенда:
застрашени зони при висока вълна с
период на повторение (ПП):
10 години 50 години
20 години 100 години
oпасност от заливане на сгради:
незастрашени
слабо застрашени (ПП > 100 год.)
средно застрашени (ПП 20 -100 год.)
силно застрашени (ПП < 100 год.)
EUROPEAN UNION
Bulgaria – Serbia IPA Cross-border Programme
“Assessment of flood risk – a base for sustainable development in upper part of Nishava
catchment” Page 16](https://image.slidesharecdn.com/metodikaenfinal-120830102552-phpapp02/85/Metodika-en-final-16-320.jpg)
Metodika en final
- 1. Програма за ТГС по ИПП България – Сърбия DEVELOPMENT OF A UNIFORM TRANS-BOUDARY METHODOLOGY FOR FLOOD RISK ASSESSMENT CONTENTS: INTRODUCTION CHAPTER ONE 1. USED TERMINOLOGY 2. EUROPEAN APPROACHES 3. LEGISLATION AND INSTITUTIONAL FRAMEWORK 4. DATABASE 5. TYPES OF FLOODS CHAPTER TWO 1. COMMON APPROACH 2. HYDROLOGY 2.1. DETERMINATION OF THE MAXIMUM RUN-OFF 2.2. CLIMATE CHANGE 3. GEODESY 3.1. COORDINATE SYSTEMS AND PROJECTIONS 3.2. DIGITAL TERRAIN MODEL 3.3. ADDITIONAL ANALYSIS OF THE DIGITAL TERRAIN MODEL 3.4. GEODESIC SHOOTING 4. HYDRAULIC MODELLING 4.1. CALCULATION METHODS AND PROGRAMMES 4.2. CREATION OF A HYDRAULIC MODEL CHAPTER THREE 1. FLOOD HAZARD MAPS 1.1. DETERMINATION OF THE INUNDATED AREAS 1.2. КCORRECTION OF THE INUNDATED AREAS 1.3. PROTECTION MEASURES 1.4. FORMATTING OF THE MAPS 2. FLOOD RISK MAPS 1.5. RISK MAPPING APPROACHES EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 1
- 2. Програма за ТГС по ИПП България – Сърбия 1.6. SOCIO-ECONOMIC ASPECTS 1.7. RISK CLASSIFICATION 1.8. FORMATTING OF THE MAPS CHAPTER ONE EUROPEAN APPROACH Czech Republic Orthophotos and topographic maps, scale of 1:10 000, are used as a basis for the preparation of flood hazard and flood risk maps in Czech Republic. The orthophotos and topographic maps are provided by the Czech Surveying Office for Mapping and Cadastre (file ZABAGED). Figure 1: Orthophoto and topographic map EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 2
- 3. Програма за ТГС по ИПП България – Сърбия Figure 2: Scheme for flood hazard and flood risk maps elaboration for given scenario (water quantity). LEGISLATION AND INSTITUTIONAL FRAMEWORK General obligations of the parties with respect to the management of flood risk and cross-border cooperation are determined by international legal frameworks such as the Water Convention of the UNECE and the Floods Directive of the EU. National legislation should set clearly defined and allocated responsibilities and rights of all institutions and organizations that are relevant to flood risk management. EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 3
- 4. Програма за ТГС по ИПП България – Сърбия Figure 3. Legislation and institutional framework in flood risk managament EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 4
- 5. Програма за ТГС по ИПП България – Сърбия Figure 4 Current organization of water management in Republic of Serbia EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 5
- 6. Програма за ТГС по ИПП България – Сърбия Figure 5 Scheme Structure of the specialized institutions in flood risk management DATABASE Categories of databases: Basic data Hydrology Hydraulics Climate Damage assessment TYPES OF FLOODS The main feature for typifying floods is their source. Depending on it, the following types of floods can be defined: "sea floods", "river flooding", "rain floods", " groundwater floodings" and "infrastructure floodings". CHAPTER TWO EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 6
- 7. Програма за ТГС по ИПП България – Сърбия 5. HYDROLOGY 5.1. DETERMINATION OF THE MAXIMUM RUN-OFF Statistical methods The statistical methods are applicable for determination of the maximum run-off in basins with built hydrometric network and an area greater than 1000 km. The statistical methods are applied in both countries. Models „rainfall – run-off” Figure 6 Model „Rainfall – run-off” Method for regionalization of the maximum run-off Eight factors and characteristics of drainage basins and river systems that are essential for the formation of maximum flow are set out in LUBW, 2007: • area of the catchment AEo [km2] • urbanized territory S [%] • afforestation W [%] EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 7
- 8. Програма за ТГС по ИПП България – Сърбия • average slope Ig [%] • river length L [km] along the main rivers of the watershed to the confluence • river length LC [km] from the center of gravity of the catchment to its estuary; • average annual rainfall in the catchment hNG [mm] • landscape factor LF [-] GEODESY DIGITAL TERRAIN MODEL A variety of sources can be used to create a terrain elevation model: topographic maps, satellite images, orthophotos, surveys of the river flow, LIDAR. The described sources are characterized by different accuracy of the topographical information. Therefore, the combined use of these sources is recommended to obtain a digital terrain model with sufficient accuracy. Figure 7 Geodesic measurements /shooting of cross-sections/ EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 8
- 9. Програма за ТГС по ИПП България – Сърбия Figure 8 Encoding of the cross section folds based on inverted cross sections of the plane Figure 9 Generation of 3D folds of the river bed terrain EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 9
- 10. Програма за ТГС по ИПП България – Сърбия Figure 10 Digital terrain model, developed on the basis of laser scanning data Figure 11 Digital terrain model of river section, developed with laser scanning data EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 10
- 11. Програма за ТГС по ИПП България – Сърбия Figure 12 conbination of laser scanning data, geometry of the facilities and folds f the terrain structure GEODESIC SHOOTINGS EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 11
- 12. Програма за ТГС по ИПП България – Сърбия Figure 13 Method of the profiles 1. HYDRAULIC MODELLING 1.1. CALCULATION METHODS AND PROGRAMMES Use of 1D model for river section calculation (i.e. HEC-RAS) In these models, the geometry of the river valley and the river bed is laid depending on multiple cross sections. The hydraulic impact on equipment and hinders in the riverbed,on the local expansion or narrowing, of the changes in the slope of the river bed, etc. can be reproduced by 1D-models of the river flow. EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 12
- 13. Програма за ТГС по ИПП България – Сърбия Figure 14 Determination of cross-sections for hydraulic measurements of the digital terrain model (based on topographic maprs 1:5000) Figure 15 Calculated inundated areas from 1D calculations 1.2. CREATION OF A HYDRAULIC MODEL Use of 2D models of the river sections (i.e. Hydro_AS-2D) EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 13
- 14. Програма за ТГС по ИПП България – Сърбия Figure 16 2D-calculation network of the basis of elevation sports connection of SRTM-elevation terrain model, (basis: Google Earth) Figure 17 Calculated inundated area with 2D hydraulic measurements (basis: Google Earth) Use of hydrologic model, based on calculation raster network for 2D calculations of the surface run-off (i.e. GSSHA model) EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 14
- 15. Програма за ТГС по ИПП България – Сърбия Figure 18 Image of the modelled area with run-off model (GSSHA) based on calculation raster network. CHAPTER THREE FLOOD HAZARD MAPS Flood hazard maps are made for the following scenarios: flooding with low security or high repetition period (extreme floods); flooding with medium security (≤ 1%), respectively, with an average repetition periods (≥ 100 years); individually, floods with high security or a small repetition period. In compliance with the flood risk directive, flood hazard maps must contain the following information: of flooding; of flooding and water levels; individually, flow velocity or the relevant water flow. EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 15
- 16. Програма за ТГС по ИПП България – Сърбия легенда: заливни дълбочини за висока вълна с период на повторение 100 години [см] залети площи площи със свободен борд < 30 см степен на застрашеност на сгради: незастрашени сгради потенциално застрашени сгради Figure 19 Borders of inundation and calcualted depths of floods during high wave with repetition period 100 years, respectively 1% security. легенда: застрашени зони при висока вълна с период на повторение (ПП): 10 години 50 години 20 години 100 години oпасност от заливане на сгради: незастрашени слабо застрашени (ПП > 100 год.) средно застрашени (ПП 20 -100 год.) силно застрашени (ПП < 100 год.) EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 16
- 17. Програма за ТГС по ИПП България – Сърбия Figure 20 Borders of inundation for floods with repetition period 10, 20, 50 и 100 years, respectively 10%, 5%, 2% и 1% security. Figure 21 Determination of the flood hazard in Wallone EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 17
- 18. Програма за ТГС по ИПП България – Сърбия Figure 22 Integration of the determination methods of the repatition and inundation of the river Figure 23 Exemplary flood hazard map EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 18
- 19. Програма за ТГС по ИПП България – Сърбия Figure 24 Exemplary flood risk map PROTECTION MEASURES If there are protective measures against flooding, it does not necessarily mean that the location is protected from flooding. Often there are protection measures which do not functioning normally due to lack of maintenace and no longer correspond to the modern technologies. Even with perfectly working facilities it must be alwasys considered that they can not provide absolute protection at a certain risk. Often the protection degree of the protection measures is not known exactly, so it is difficult to accurately estimate the effect of the measures, in example for HQ100 FORMATTING OF THE MAPS According to the Floods Directive, the flood risk assessment should covere the negative impacts on the following protected categories "human health", "environment", "cultural heritage" and "business". A prerequisite for achieving this goal is the definition of clear criteria for assessing the negative effects on each protected category separately. CALSSIFICATION OF THE RISK EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 19
- 20. Програма за ТГС по ИПП България – Сърбия Figure 25 Exemplary map of classification of the inundated areas EUROPEAN UNION Bulgaria – Serbia IPA Cross-border Programme “Assessment of flood risk – a base for sustainable development in upper part of Nishava catchment” Page 20