Revision as of 20:32, 30 January 2024 view source Tuflowduncan (talk \| contribs) Bureaucrats, Administrators 1,208 edits →Spacing of Road Gullies (BS EN 124 and BS7903) Tag: Visual edit ← Older edit		Revision as of 21:22, 30 January 2024 view source Angelos Livogiannis (talk \| contribs) 182 edits No edit summary Tag: Visual edit: Switched Newer edit →
Line 76: === City of West Torrens === [https://www.unisa.edu.au/research/sustainable-infrastructure-and-resource-management/australian-flow-management-group/stormwater-drainage-hydraulic-study/city-of-west-torrens/ City of West Torrens Pit Inlet Curves] == UK Water Industry Research (UKWIR) Inlet Capture Tool ==▼ In 2023, the UK Water Industry Research (UKWIR) Limited released the Modelling Sewer Inlet Capacity Restrictions Report [https://ukwir.org/modelling-sewer-inlet-capacity-restrictions/ Modelling Sewer Inlet Capacity Restrictions Report]. The main aim was to develop a sewer modelling methodology to enable the representation of inlet inflow restrictions, focusing on the development of a new 1D model approach to provide more accurate model sewer flooding predictions. The new modelling approach has been devised by combining the findings from a literature review and the development of semi-empirical relationships from academic studies which investigated factors affecting inlet capacity. The new approach allows for 2 types of gully response reflecting 2 flow conditions: Subcritical flow on a shallow road gradient and Supercritical flow on a steep road gradients. A threshold of 0.02 is used to distinguish between shallow and steep road gradients. The reported equations can be used for the production of input inlet curves for TUFLOW 1D pit inlet modelling. ▼ A template for the generation of the UKWIR Inlet Curve can be downloaded from [https://downloads.tuflow.com/Other/Inlet_Spreadsheets/Inlet%20Curve%20Capture%20tool%20v4.xlsx here]. The template determines both Subcritical Head-Discharge and Supercritical Head-Discharge relationships obtained from the Modelling Sewer Inlet Capacity Restrictions Report based on user input values of water depth (in metres). Two sets of curves can be generated, curves based on default parameters, and those based on user-defined parameters.▼ == Page Under Construction (Section: Spacing of Road Gullies) == == Spacing of Road Gullies (UK adoption BS EN 124 and BS7903) == The following section describes the method to determine the spacing of road gratings, according to the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ Spacing of Road Gullies] guidance ('''BS EN 124''' and '''BS 7903'''). Line 91 ⟶ 86: * Cross-fall, ''S<sub>c</sub>'' (also expressed as a fraction). * Manning’s roughness coefficient, ''n''. Usually ''n'' = 0.017 for a conventional road surface. Other values are given in the following '''Table 1'''. (For more details, please see Section: 4.3, Table 1 of the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ guidance]). '''Table 1:''' Values of Manning's ''n'' Line 103 ⟶ 98: '''A) Use of Tables for determining the flow capacity of gullies and maximum spacings for gully gratings'''<br> Equations given in Section 5 of the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ guidance] are used for the calculation of the Spacing of Road Gullies. Design tables have been compiled to present a quick design approach. Tables can be found in Annex C. Annex C includes design tables for the grating types: Types P, Q, R, S and T. The Design Tables C2-C6 in Annex C of the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ guidance] present the area that can be drained for an intermediate gully and a range of crossfall and gradient of flow widths. For the design tables a rainfall intensity of 50mm/h and Manning’s ''n'' = 0.017 are considered. For ease of access, Tables C2-C6 are replicated in the Spacing of Road Gullies file here [Excel File]. Please see, tabs: Type P, Type Q, Type R, Type S and Type T. The Excel file provides tables like the following examples and their corresponding graphs. Line 113 ⟶ 108: '''B) Calculation of Gully Spacings based on Equations''' <br>Alternatively, the equations given in Sections 5 of the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ guidance] can be used for the Spacing of Road Gullies, directly. The method requires the calculations of the Flow capacity of the kerb channel and Flow collection efficiency of the gully grating. As a first step, a gully grate type: P, Q, R, S or T should be selected. The selection of the grating Type will determine the design value ''G<sub>d</sub>'' (grating parameter) from '''Table 2'''. (For more details, please see Annex B of the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ guidance]). '''Table 2:''' Determination of grating type ''G<sub>d</sub>'' Line 128 ⟶ 123: Further, a Water Depth against the kerb ''H'' (m) range should be provided. (Please note: The depth range can be changed, but the following equations that are used to calculate the flow capacity are only valid up to the kerb height). With the above parameters, the calculations of i) The Flow width (''B'' in m), ii) the Cross-sectional area (''A<sub>f</sub>'' in m2), iii) Hydraulic radius (''R'' in m), iv) Flow rate (''Q'' in m3/s) and v) Flow collection efficiency (''ŋ'' (%)) based on the Equations 6-10 which are presented in Section 5 of the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ guidance] can be completed. Finally, the resulting depth-discharge data can be used in the pit inlet curves.<br> The Spacing of Road Gullies Excel file above includes a calculation tab which can be used for the completion of the calculation process. Based on calculations and Equations (11) and (12) of the [https://new.sthelens.gov.uk/media/330117/5126_ha-102_00.pdf/ guidance] the maximum spacings for gully grating can be calculated. '''Key assumption'''<br>'''Note:''' This method assumes that the route the flow takes around the trap limits the discharge from the gully pot to 10 l/s. This limit is effective in both directions, so any number of negative head on the gully would create -10 l/s flow back up through the gully and flood onto the road. <br> ▲== UK Water Industry Research (UKWIR) Inlet Capture Tool == ▲In 2023, the UK Water Industry Research (UKWIR) Limited released the Modelling Sewer Inlet Capacity Restrictions Report [https://ukwir.org/modelling-sewer-inlet-capacity-restrictions/ Modelling Sewer Inlet Capacity Restrictions Report]. The main aim was to develop a sewer modelling methodology to enable the representation of inlet inflow restrictions, focusing on the development of a new 1D model approach to provide more accurate model sewer flooding predictions. The new modelling approach has been devised by combining the findings from a literature review and the development of semi-empirical relationships from academic studies which investigated factors affecting inlet capacity. The new approach allows for 2 types of gully response reflecting 2 flow conditions: Subcritical flow on a shallow road gradient and Supercritical flow on a steep road gradients. A threshold of 0.02 is used to distinguish between shallow and steep road gradients. The reported equations can be used for the production of input inlet curves for TUFLOW 1D pit inlet modelling. ▲A template for the generation of the UKWIR Inlet Curve can be downloaded from [https://downloads.tuflow.com/Other/Inlet_Spreadsheets/Inlet%20Curve%20Capture%20tool%20v4.xlsx here]. The template determines both Subcritical Head-Discharge and Supercritical Head-Discharge relationships obtained from the Modelling Sewer Inlet Capacity Restrictions Report based on user input values of water depth (in metres). Two sets of curves can be generated, curves based on default parameters, and those based on user-defined parameters. == How to Translate On-Grade Approach Flow / Pit Capture Flow Curves to Depth / Discharge Curves for use in TUFLOW ==

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