& Construction
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Integrated BIM tools, including Revit, AutoCAD, and Civil 3D
& Manufacturing
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Professional CAD/CAM tools built on Inventor and AutoCAD
Integrated BIM tools, including Revit, AutoCAD, and Civil 3D
Professional CAD/CAM tools built on Inventor and AutoCAD
Transcript
00:04
It is often necessary to edit a mesh using various objects to provide more detail
00:10
and improve the representation of the underlying topography.
00:15
These mesh editing objects can be manually added or taken from external files,
00:21
layers displayed in the GeoPlan view, or objects within the network.
00:34
directly in the 2D engine, and allow flow to be transferred between two areas of a 2D zone.
00:42
A conduit is defined as a 2D conduit if its type is Conduit (2D) or Linear Drainage (2D).
00:52
The Conduit (2D) type represents a drainage structure such as a culvert,
00:58
which may be located beneath a road.
01:01
In addition, momentum is preserved in the 2D conduit/2D zone connection,
01:08
providing a better representation of the actual flow for this type of hydraulic structure.
01:14
Note that since 2D conduits are sub-divided into a series of computational cells,
01:20
small conduits will introduce small elements into the model, which could dramatically increase the run time.
01:29
The Linear Drainage (2D) type represents a linear gully, such as a slot drain,
01:36
which is connected vertically to the 2D surface.
01:40
A typical modelling scenario for this functionality is detailed drainage site projects,
01:47
where the 2D modelling resolution is 100m2 or less.
01:52
In this example, conduit 2D links and connect 2D nodes
01:57
have been used to represent an underpass that forms an important flow route.
02:03
This allows the flow under the embankment to be represented within the 2D engine.
02:09
Momentum will be maintained and volume balance issues between the 1D and 2D engines can be avoided.
02:18
The Node type is set to Connect 2D,
02:22
and the Connection type is set to 2D,
02:25
allowing direct connection between the conduit 2D link and the 2D element.
02:32
The same node and connection type are used at both ends of the link, to allow flow to be exchanged with the 2D zone at either end.
02:42
A conduit is connected between the two nodes with a Conduit type set to Conduit (2D).
02:49
This limits the available options.
02:52
The location of the nodes should be sighted so that there is good agreement between the 2D element - ground level
03:00
and conduit (2D) upstream and downstream invert levels.
03:05
Adjustment of locations can be made after the mesh is generated,
03:10
as adding a conduit (2D) link does not require the mesh to be regenerated—although adding a linear drainage (2D) link
03:20
does require regeneration.
03:23
Looking at a simulation of this area, the flow can pass under the embankment represented in the 2D element levels,
03:32
through the conduit (2d) link, and out onto the 2D elements on the other side.
03:39
This means that if the depth reaches a sufficient level,
03:43
the embankment can be overtopped via the 2D elements.
03:48
Note that because the conduit (2D) link uses momentum as part of the boundary condition for the conduit,
03:55
it has been found to perform poorly in areas of deep and stagnated water.
04:02
If this condition occurs in your model, it may be necessary to use the outfall 2D and conduit type links
04:10
for a better hydraulic representation.
Video transcript
00:04
It is often necessary to edit a mesh using various objects to provide more detail
00:10
and improve the representation of the underlying topography.
00:15
These mesh editing objects can be manually added or taken from external files,
00:21
layers displayed in the GeoPlan view, or objects within the network.
00:34
directly in the 2D engine, and allow flow to be transferred between two areas of a 2D zone.
00:42
A conduit is defined as a 2D conduit if its type is Conduit (2D) or Linear Drainage (2D).
00:52
The Conduit (2D) type represents a drainage structure such as a culvert,
00:58
which may be located beneath a road.
01:01
In addition, momentum is preserved in the 2D conduit/2D zone connection,
01:08
providing a better representation of the actual flow for this type of hydraulic structure.
01:14
Note that since 2D conduits are sub-divided into a series of computational cells,
01:20
small conduits will introduce small elements into the model, which could dramatically increase the run time.
01:29
The Linear Drainage (2D) type represents a linear gully, such as a slot drain,
01:36
which is connected vertically to the 2D surface.
01:40
A typical modelling scenario for this functionality is detailed drainage site projects,
01:47
where the 2D modelling resolution is 100m2 or less.
01:52
In this example, conduit 2D links and connect 2D nodes
01:57
have been used to represent an underpass that forms an important flow route.
02:03
This allows the flow under the embankment to be represented within the 2D engine.
02:09
Momentum will be maintained and volume balance issues between the 1D and 2D engines can be avoided.
02:18
The Node type is set to Connect 2D,
02:22
and the Connection type is set to 2D,
02:25
allowing direct connection between the conduit 2D link and the 2D element.
02:32
The same node and connection type are used at both ends of the link, to allow flow to be exchanged with the 2D zone at either end.
02:42
A conduit is connected between the two nodes with a Conduit type set to Conduit (2D).
02:49
This limits the available options.
02:52
The location of the nodes should be sighted so that there is good agreement between the 2D element - ground level
03:00
and conduit (2D) upstream and downstream invert levels.
03:05
Adjustment of locations can be made after the mesh is generated,
03:10
as adding a conduit (2D) link does not require the mesh to be regenerated—although adding a linear drainage (2D) link
03:20
does require regeneration.
03:23
Looking at a simulation of this area, the flow can pass under the embankment represented in the 2D element levels,
03:32
through the conduit (2d) link, and out onto the 2D elements on the other side.
03:39
This means that if the depth reaches a sufficient level,
03:43
the embankment can be overtopped via the 2D elements.
03:48
Note that because the conduit (2D) link uses momentum as part of the boundary condition for the conduit,
03:55
it has been found to perform poorly in areas of deep and stagnated water.
04:02
If this condition occurs in your model, it may be necessary to use the outfall 2D and conduit type links
04:10
for a better hydraulic representation.
2D conduits can be used in a 2D simulation to introduce unidimensional hydraulic structures directly in the 2D engine, and allow flow to be transferred between two areas of a 2D zone.
A conduit is defined as a 2D conduit if its type is Conduit (2D) or Linear Drainage (2D):
The Conduit (2D) type represents a drainage structure such as a culvert, which may be located beneath a road. In addition, momentum is preserved in the 2D conduit/2D zone connection, providing a better representation of the actual flow for this type of hydraulic structure. Since 2D conduits are sub-divided into a series of computational cells, small conduits will introduce small elements into the model, which could dramatically increase the run time.
The Linear Drainage (2D) type represents a linear gully, such as a slot drain, which is connected vertically to the 2D surface. A typical modelling scenario for this functionality is detailed drainage site projects, where the 2D modelling resolution is 100m2 or less.
In this example, conduit 2D links and connect 2D nodes have been used to represent an underpass that forms an important flow route. This allows the flow under the embankment to be represented within the 2D engine. Momentum will be maintained and volume balance issues between the 1D and 2D engines can be avoided.
The Node type is set to Connect 2D, and the Connection type is set to 2D, allowing direct connection between the conduit 2D link and the 2D element. The same node and connection type are used at both ends of the link, to allow flow to be exchanged with the 2D zone at either end.
The Conduit type is set to Conduit (2D), which limits the available options.
The location of the nodes should be sighted:
Adjustment of locations can be made after the mesh is generated, as adding a conduit (2D) link does not require the mesh to be regenerated—although adding a linear drainage (2D) link does require regeneration.
The flow can pass under the embankment represented in the 2D element levels, through the conduit (2D) link, and out onto the 2D elements on the other side. This means that if the depth reaches a sufficient level, the embankment can be overtopped via the 2D elements.
Because the conduit (2D) link uses momentum as part of the boundary condition for the conduit, it has been found to perform poorly in areas of deep and stagnated water. If this condition occurs in the model, it may be necessary to use the outfall 2D and conduit type links for a better hydraulic representation.
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