Rainfall Overlay tutorial
Getting Started
- Open the Tygron Engine, logon with user name and password and open the project Inun Test NL
- Download and unpack the content of this zip-file on your desktop: [1]
Editing terrain: importing surface water
First we add water to the terrain model of our project:
- Go to Terrain in the ribbon and select Import GeoJSON file
- Press Select File and import the file openwater.geojson from the tutorial
- Select Water from the Import as Terrain Type: selection menu
File:RFO Tutorial ImportTerrainFile.png
Press Send. You have added the canals of our water system!
File:RFO Tutorial TerrainEdited.png
Adding a Rainfall Overlay
- Go to Overlays, in the GeoData ribbon and select Add Rainfall. The rainfall indicator appears on the left-side-panel
- Open the Rain Overlay Wizzard by clicking on the Configuration Wizard button in the right-side-panel
The Rainfall Overlay Wizard will appear:
File:RFO Tutorial WizzardStartup.png
Step 1: defining the weather
Press Next to proceed to the Weather panel, here the user can define rainfall and evaporation input. Change all numbers and the according to this picture: File:RFO Tutorial Weather.png
By this setting you have defined a rainfall event:
- Of two peaks in 120 minutes
- With a total rainfall amount of 100mm
- With a dry period after rainfall of 120 minutes, so a total simulation time of 4 hours
Reference evapotranspiration will be assumed on 1.5mm/day
Step 2: setup of the water system
Press next to proceed to the introduction screen Setup Water System
Step 2.1: adding water level areas
Press next to the screen for importing water areas. A water level area is an area with a spatially uniform water level varying in time. Variation is caused by rainfall + evaporation on the surface water, inflow from sewer areas, inflow from the surface and groundwater inflow.
There are three options:
- Import Water Areas: allows you to import a set of water level areas from an external dataset
- Generate Water Areas: allows you to define 1 water level area for your project area
- Do Nothing: the surface water system effectively has infinite storage
File:RFO Tutorial ImportWaterLevelAreas.png
Press Import Water Areas and press Select File. Browse to the file: waterlevelareas.geojson. Set the following:
- Set name based on attribute, and select the NAME attribute from the geojson file.
- Import the OUTLET attribute and assign it to the OUTLET key. Here a pump capacity (m3/s) is specified. In water areas with the pump capacity defined, water will be extracted with the pump capacity. Extracted water via the pump is assumed to be discharging outside the project domain.
- Import the WATER_LEVEL attribute and assign it to the WATER_LEVEL key. Here the initial water level in the water area is defined in m + reference (being NAP in the Netherlands)
File:RFO Tutorial WaterLevelAreas.png
Press send: you have now successfully defined your water areas!
Step 2.2: initial groundwater level
In step 2.2, you can specify ground water levels. By default, ground water levels are assumed to be the same as the water level in the water level area (see previous section). Alternatively, the user can specify pre-defined initial groundwater levels (GHG,GLG and GVG for the Netherlands) or a GeoTiff with ground water levels in m + reference (NAP in The Netherlands).
File:RFO Tutorial ImportGWL.png
We will not do that as part of the tutorial and press Next
Step 2.3: adding sewer areas
Sewer districts are represented by areas which have one storage value (mm), uniform in space. Sewer storage will vary in time by sewer inflow from connected buildings (buildings, roads, etc), pumped outflow to a WWTP and sewer overflow to surface water.
Upload your GeoJson file by selecting Import Sewers in the Sewers screen.
File:RFO Tutorial ImportSewerAreas.png
Press Select File, browse to the file: sewerdistricts.geojson. Set the following:
- Set name based on attribute, and select the NAME attribute from the geojson file.
- Import the SEWER_PUMP_CAPACITY attribute and assign it to the SEWER_PUMP_SPEED key. Here a pump capacity (m3/s) is specified. In water areas with the pump capacity defined, water will be extracted from the sewer district with the pump-rate. Extracted water via the pump is assumed to be discharging outside the project domain.
- Import the SEWER_STORAGE attribute and assign it to the SEWER_STORAGE key. This is the sewer storage in meters
File:RFO Tutorial SewerAreas.png
Press send: you have now successfully defined your sewer districts!