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Figure 9. Water User node, constituent concentration
Weir node
Constituent modelling at the Weir node has the same options as the Storage node (see Figure 6 and Figure 8 above). The Weir node has a configurable storage routing upstream link, a constituent decay model on this link is configurable through the Constituent Models table.
Scenario Transfer node
Along with flows, constituents are also transferred when using a Scenario Transfer node.
Constituents and Ownership
Constituent concentrations are assumed consistent across all owners, according to the concentration of the associated water body.
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Constituents can be configured for storage routing links in the feature editor (Figure 9). In this screen, you can specify the link’s constituent concentration when the simulation begins. This parameter assigns a concentration for each modelled constituent in the scenario for the markers created in that link during the model initialisation. You can also specify the instream processing model, the parameters of which can then be configured by selecting Configure…
For each constituent, you can specify an increase in concentration from different sources, similar to constituents in the storage node (Figure 9). The parameters are:
- Additional Inflow Load– specify the amount of constituent mass to be added to the storage routing link per time-step. It is not specific where this constituent mass comes from;
- Groundwater– concentration of the constituent entering the link via groundwater flow; and
- Timeseries Flux – concentration of the constituent entering the storage routing link viaTimeseries Flux.
Note that both Groundwater and TimeseriesFlux need to be configured on the storage routing link for constituents to enter the link using these sources - see Groundwater and Storage routing - Timeseries Flux.
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Note: Unless there is either an initial storage or initial flow defined, there will be no constituent mass in the link at the start of the model simulation. |
Figure 9. Storage routing link, constituents
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Constituents in a catchment model have a constituent generation model and a constituent filter model for each sub-catchment/functional unit (FU) combination. To configure these, use the Constituent Model Configuration dialog (Figure 3), which is opened by navigating to Edit constituent sources.
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These describe how constituents (eg. sediments or nutrients) are generated within a functional unit and the resulting concentrations or loads passed to the filter model. Click on any constituent to view the associated FU and generation model for each sub-catchment.
Assign and parameterise generation models for a constituent as follows:
- Click on the constituents under Generation Models (in the tree menu).
- Assign a model to the sub-catchment/FU combination:
- Click on the cell in the Model column that you want to change; and
- Click on the drop-down arrow that appears and choose the required model from the menu;
- Assign input data (if relevant) to the model; and
- Parameterise the filter model. Depending on the chosen model, the right-side of the table will populate with the associated default parameters. Click on the cells and edit these values.
The available constituent generation models are:
- EMC/DWC – the Event Mean Concentration (EMC) / Dry Weather Concentration (DWC) model applies two fixed constituent concentrations (EMC & DWC) to an FU to calculate the total constituent load.
- Export rate – this model applies a fixed constituent generation rate to a functional unit (FU) to calculate total constituent load. It requires only a single parameter so is quick to use and therefore useful for exploring sensitivity.
- Nil Constituent – this model is used as a substitute constituent generation model where no constituent load needs to be modelled for a given constituent from a given FU
- Observed concentration – this option allows you to assign observed quick flow and slow flow concentrations.
- Power Function – this model fits a rating curve describing the relationship between constituent concentration or load and discharges. It is a straight power curve, where flow in ML/d has been used to generate a relationship with the solute concentration (mg/L),
- Power Function (flow in mm) – this model is the same as the Power Function model, but uses a normalised power curve, where flow in mm/d has been used to generate a relationship with the solute concentration (mg/L).
The default constituent generation model is Nil Constituent.
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Filter models represent any transformation of constituents between generation within the FU and arrival at the link upstream of the sub-catchment node. Filter models process constituents within the FU and as with constituent generation models, are applied to FUs. Follow the same steps outlined for generation models to assign, add input data and parameterise constituent filter models.
The available constituent filter models are:
- 1st Order Kinetic Model k-C* – reduces the concentration of constituent leaving an FU as a result of a treatment facility (eg. a grass filter strip).
- Load-based nutrient delivery ratio – reduces the amount of nutrient leaving an FU in the quick flow as a function of the amount of load generated in the FU.
- Load-based sediment delivery ratio – reduces the amount of sediment leaving an FU as a function of the amount of load generated in the FU.
- Pass-through– preserves the amount of constituent generated in an FU and passes this to the downstream sub-catchment node.
- Percentage removal– removes a fixed percentage of the constituent associated with the quick flow of the FU and a fixed percentage of the constituent associated with the baseflow
- RPM filter – The riparian particulate model (RPM) is used to model the trapping of sediment particles in riparian buffers and so reduce the load of sediment and associated constituents to streams. It is intended principally for catchment-scale applications.
The default constituent generation model is Pass-through.
Linking constituent generation or filter models
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Note: This functionality is currently under development and not all models can be linked. The description that follows is an illustration of what can be undertaken in Source. |
Constituent generation and filter models may require one or more of their parameters to originate from another generation or filter model. The load-based nutrient delivery ratio (NDR) filter model depends on the input of the load-based sediment delivery ratio (SDR) filter model. To configure constituent model linking between these two models for a given sub-catchment/FU combination and constituent source, assign an SDR model to the sediment constituent, and an NDR model to each other appropriate constituent. You then need to define a linkage between the SDR quickflowConstistuentIn parameter and the quickflowSedimentIn parameters of the NDR models. Once the linkage is created, the SDR model is run before the NDR models, allowing the correct flow of data at the right point in time.
To link an NDR model to an SDR model, in the Constituent Model Configuration dialog (Edit
..):- From the tree menu, under filter model, select the constituent representing sediment
- For the appropriate sub-catchment/FU combinations:
- assign the load-based sediment delivery ratio model, and
- configure the parameters of the model
- From the tree menu, under filter model, select an appropriate constituent (representing nutrients)
- For the same sub-catchment/FU combinations:
- Assign the load-based nutrient delivery ratio model
- For the parameter quickflowSedimentIn click the ellipsis button (...) next to Not Linked to open the Define Constituent Model Linkage dialog.
- Select the sediment constituent from the list of constituents, the constituent source, the Load-based sediment delivery model), and finally the parameter whose value will be used as input (quickflowConstituentIn).
- Click OK to close the dialog.
- Configure the rest of the parameters of the model.
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Note: Source detects circular dependencies, and will notify you if a defined link needs to be corrected prior to proceeding. |
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Constituent sources allow you to configure more than one constituent generation and/or filter model for a given sub-catchment/FU combination. Each constituent source assigned to a constituent/sub-catchment/FU combination allows you to select different constituent models or model parameters. For each source, the selected generation or filter model and its parameters are applied across the entire area of that sub-catchment/FU. An example use for constituent sources is to model the constituents from a fire in the forest and agriculture functional units of SC #1. First, two sources are defined, Default and Fire (Figure 1). Then the default source is used to model the constituent generation and filtering under natural conditions for both the forest and the agriculture FUs in SC#1. Then the fire source is used to model the additional constituent generation and filtering that results from the fire (Figure 2).
The first step when configuring constituent sources is to add sources to the Constituents Configuration dialog (as described in Defining constituents, Figure 1). There is always at least one constituent source that is the default, it is indicated by a green tick (Figure 1), and cannot be deleted. You can change which source is the default using the Set as Default contextual menu.
For each constituent, every sub-catchment/FU combination is assigned the default constituent source for both constituent generation and constituent filtering. You can change the constituent source from the default or add or remove additional constituent sources in the Constituent Model Configuration dialog (Figure 2), which is opened by navigating to Edit ...
To change a constituent source for a constituent generation or filter model:
- Select the constituent you wish to change the source for (the tree view on the left) under either the filter or generation model (any change to the source is automatically applied to both models for that constituent);
- Select the row with the appropriate sub-catchment/FU combination;
- Right-click and choose Add Constituent Source » Current Constituent » <source name>. This will add a new row to the table, allowing you to assign and parameterise a new constituent generation or filter model for the selected constituent/sub-catchment/FU.
You can also undertake the following actions using the same contextual menu:
- The process to remove a constituent source from an FU is identical to adding one. Choose Remove Constituent Source » Current Constituent » <source name>. Note that at least one constituent source must exist at all times. If all sources have been removed, a new row with the default source will be automatically added;
- Bulk the assignment of a source to multiple constituents can be made using the Add/Remove Constituent Source » All Constituents. This will add that constituent source to that sub-catchment/FU combination for all constituents.
- You can assign the same constituent source to several sub-catchment/FU combination by selecting multiple rows, then right-clicking and choosing the desired constituent source menu item.
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