Chamber stormwater controls are underground storage solutions which use pre-built chambers to house the stored volume.
Note - Only the desired facility criteria must be populated; for example for flow routing simulation, only the Dimension tab must be populated, while the rest of the facility description tabs can be left blank.
Exceedence Level - Represents the level (above datum) of the Surface Data model (TIN) is present the Exceedence Level will automatically be picked up from the centre of the icon or from the lowest point on the bioretention perimeter if an outline has been drawn. This allows a Status of Flood Risk to be assigned to the system on the Summary. Above the Exceedence Level, water will be stored above the ground and then allowed to drain back into the network. The area used for the flooded volume is 1000 m² .above which flooding is reported. This may be the level that interacts with the ground surface or the top of an embankment, whichever is higher. If a
Depth - This is the depth of the input data, including chambers and Embedded dimensions. This can be less than the difference between the Exceedence and Base levels; in this case, the system is assumed to be buried. The depth is kept up to date at all times, and can be changed by adjusting the parameters of the chamber being used, or the amount of Embedded above or below the chambers.
Base Level - Represents the level (above datum) of the base of the Stormwater control.
Number of Chambers - This specifies how many chambers are present within the system. This number is the primary adjustable value for changing the contained volume in the Stormwater control.
Number of Rows - Details the number of rows to be used by the structure. This value is rarely adjusted by the system, and is used to generate a shape for the structure. Rows will always be evenly sized, as far as possible.
Distance Between Rows - If rows are not to be packed tightly to each other, the space between them can be specified. This allows the structure to more accurately represent the built site, as well as to account for any additional fill material needed.
A single chamber is a shaped structure that is used to hold the water underground. Chambers typically come in one of three categories based on their cross section; An elliptical arch, a complete circle (such as a pipe), or a Box Culvert. All chambers within a drainage system are assumed to be identical. If Custom is selected, a cross section can be input manually via the Define Chamber form. The resulting width and height will be visible in the usual text boxes - these values are for reference only.
Chamber Type - This dropdown allows you to choose the category of Chamber you would like to specify. If none of the available options are suitable, a cross section can be manually input using the Custom option.
Chamber Length - This specifies the length of a single chamber.
Wall Thickness - Can be used to set a thickness for your Chamber walls; this will be excluded from Volume calculations.
Diameter / Base Width - The internal horizontal width of the structure. The maximum internal width should be used.
Height - The internal vertical height of the structure. Must be specified for all chambers other than pipes.
Corner Splay - The corner splay to use. This is only an option for Box Culvert chambers. If desired, this can be left at 0 to create a simple square or rectangular chamber.
Define Chamber - This will open the Define Chamber window to allow specification of the chamber manually.
A chamber Drainage system can be created with or without regard for the surrounding substrate. If Embedded Parameters are disabled, the only volume available is that provided by the chambers. With Embedded enabled, the chambers are assumed to be surrounded by a fill material with the given void ratio, with water being able to move between the two mediums. Total retention volume includes the available storage within the embedded material.
Void Ratio - The void ratio of the Embedded Fill material.
Height Above/Below - The height of the fill material above and below the chambers. Measuring is done from the very outside of the chambers i.e. including the wall thickness.
Sides - The amount of buffer to add to the side of each of the endmost rows.
Ends - The amount of Buffer to add to the end of each row of chambers.
The preview box shows the user a top down view of the chamber drainage system, including the buffer space (if any). This box will display when the minimum amount of information is entered by the user: at least Chamber Length and Width.
The radio buttons to the top right allow switching between the top down plan view, and the end-on section view showing the cross sections of the chambers. The title gives a strong 'at a glance' look at the structure, showing the Chamber name, number of chambers and rows, as well as the total retention volume (including embedded, if enabled).
The Sizing Calculator option allows the user to re-size the Chamber by specifying a volume and a parameter to modify to achieve the desired volume. The Sizing Calculator is discussed in more detail in the Stormwater Control Sizing Calculator section.
The number of rows is never changed when using the Sizing calculator. Please note that with large values of Distance Between Rows or Sides/Ends embedded, the sizing can be quite sensitive to the number of rows.
Explore the Inlets page for more details on the different types of Inlets that can be specified.
Explore the Outlets page for more details on the different types of Outlets that can be specified.
Side Infiltration Rate - Defines the rate of infiltration through the sides of the structure. This should be determined from a performance site test.
Base Infiltration Rate - Defines the rate of infiltration through the base of the structure. If Embedded options are disabled, the footprints of all the individual chambers are used instead of the SWC base dimensions.
Interception Volume - This represents the volume of water that enters the stormwater control that is permanently held within it. Once full it can be emptied by evapotranspiration only.
Evapotranspiration - The amount of water lost to the environment due to evaporation, transpiration and evapotranspiration. Used by the software during analysis. First the evapotranspiration removes water held in the Drainage System, then it removes water from the interception storage volume.
Routing Method - This can be set to No Delay or Simple Time Delay. With No Delay, the time of travel will be assumed to be 0; with a simple time delay, a time of travel can be entered.
Time of Travel - Can only be entered if Simple Time Delay is selected. The value can either be put in directly, or else can be derived from a Conductivity value (entered using the Calculator button).
Name - Name of pollutants. This is populated based on the Pollutants set up as part of the Site Data.
Background Concentration - Value below which the pollution concentration cannot fall during analysis. When concentration reaches this level, no further removal occurs.
Percentage Removal - Available if Percentage Removal entered. The value entered will be deducted from the Inflow into the system.
τ - The decay time constant or (mean) lifetime of the pollutant. It can be entered manually or calculated from the decay constant or decay half-life. See Pollutant Removal Method - First Order Decay for more details.