Manhole Simple Loss Example

From Tuflow
Revision as of 16:52, 26 May 2021 by Tuflowduncan (talk | contribs) (Created page with "=Intro= ==Example 1: Single Incoming/Outgoing Pipe with No Incoming Angle or Drop== <br> A simple TUFLOW/ESTRY model was set up as shown in Figure 1 with the parameters for t...")
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search

Intro

Example 1: Single Incoming/Outgoing Pipe with No Incoming Angle or Drop


A simple TUFLOW/ESTRY model was set up as shown in Figure 1 with the parameters for the manhole and the links upstream/downstream of the manhole shown in Table 1.
Schematic 1.png
Figure 1: Example Model 1 Network Schematic
Long Profile 1.png
Figure 2: Example Model 1 Long Section

Parameter Upstream Conduit Downstream Conduit Manhole
ID UC-2 DC-1 Manhole
Type R R R
Invert Level (m AD) N/A N/A 99.6
Upstream Invert Level (m AD) 99.8 99.7 N/A
Downstream Invert Level (m AD) 99.7 99.6 N/A
Width(m) 1 N/A 1
Form Loss 0 1 N/A
Flow Width(m) N/A N/A 1.8
K_Fixed N/A N/A 2
Km N/A N/A 1

Table 1: Relevant Model Parameters for Hand Calculations

The model was run with a steady inflow of 2m3s-1. The resulting losses from the 1 hour steady inflow simulation are presented in the following figure.
Manhole Results 1.png
Figure 3: Example Model 1 Results-Loss Coefficients

Example 1 - Entry Losses

Entry losses are applied as an exit loss on the incoming conduit and are calculated as follows. K entry.PNG
Where: Vp.PNG
With other parameters defined in the section above. The calculated flow area in the manhole is 3.6m2 and 1m2 in the adjacent culvert whilst the flow is 2m3/s for both Qp and Qom. Therefore, Vm equals: Vm1.PNG
And Vp: VP1.PNG
Using these in the Kentry equation provides a loss coefficient of: K entry1.PNG
The value matches the downstream loss coefficient for the upstream conduit shown in Figure 3. The loss values are also shown in the *_TSL_P.shp file with the third value for the upstream conduit providing the entrance loss value.

Example 1 - Exit Losses

Exit losses are applied to the upstream end of the outgoing conduit and are calculated as follows: K exit.PNG
From table 1, we can see that Km is set to 1. Ap and A’m are 1m2 and 3.636m2 respectively. Therefore, Kexit is: K exit1.PNG

Figure 3 shows that the calculated value matches those provided in the TUFLOW results. The value is also reported as the first value for the downstream conduit in the *_TSL_P.shp layer.

Example 1 - Outgoing Conduit Losses

The loss coefficient for the outgoing pipe represents the losses due to the incoming angle of the upstream conduit, any drops in inverts levels between the incoming and outgoing conduits, bend losses and any additional form losses. It is calculated as follows:

K outletpipe.PNG

The default value of KBend_max is set to 4 but can be changed via the 1d_mh K_Bend_Max attribute. As shown above we have no angle for the incoming pipe and no drop in invert levels. Table 1 shows the K_Fixed is equal to 2 and the outgoing pipe has a form loss coefficient, to represent bend losses of 1. Therefore Koutletpipe is: K outletpipe1.PNG

This matches the value within Figure 3 and the middle value for the downstream conduit in the *_TSL_P.shp, representing the outlet conduit losses, of 3.

Example 2: Single Incoming/Outgoing Conduit with Incoming Bend and Drop in Invert Levels


In this example, we will use the same simple setup but this time there is a 90 degree angle between the incoming and outgoing pipe as shown in the plan view in the figure below.
Schematic 2.png
Figure 4: Example Model 2 Network Schematic

There is also a drop between the invert elevation of the incoming and outgoing conduits as shown in the difference in invert levels in table 2 below and the long profile in figure 5 . All other model parameters were kept the same including boundary inflows.

Parameter Upstream Conduit Downstream Conduit Manhole
ID UC-2 DC-1 Manhole
Invert Level (m AD) N/A N/A 99.4
Upstream Invert Level (m AD) 99.8 99.5 N/A
Downstream Invert Level (m AD) 99.7 99.4 N/A

Table 2: Updated Model 2 Parameters for Hand Calculations

Long Profile 2.png
Figure 5: Example Model 2 Long Profile

The resulting simulated losses are shown in the below figure 6.
Manhole Results 2.png
Figure 6: Example Model 2 Results-Loss Coefficients

Example 2 - Entry Losses

In this example, the flow area in the manhole is 4.12m2 and 1m2 in the adjacent culvert whilst the flow is 2m3/s for both Qp and Qom. Therefore, Vm equals: Vm2.PNG
And Vp: Vp2.PNG
From this: K entry2.PNG

Which matches the value in figure 6.

Example 2 - Exit Losses

In this example, A'm is 4.12m2, therefore Kexit:K exit2.PNG

Which matches the result in figure 6.

Example 2 - Outgoing Conduit Losses

On this occasion, we have an 90 degree angle between the incoming and outgoing conduit. Therefore, we need to calculate Kθ using the following equation: Ktheta.PNG
Qf is calculated as: Qf.PNG
Qp and Qom are both 2m3s-1 and therefore Qf is equal to 1. The incoming conduit angle is 90 degrees which is cancelled out by the denominator. Kθ is therefore:Ktheta1.PNG

We also have a drop between the incoming and outgoing pipes. Kdrop which represents losses due to this drop is calculated as follows:Kdrop.PNG

Which is:Kdrop 1.PNG

Therefore Koutletpipe is:K outletpipe2.PNG

This matches the simulated value in figure 6.

Example 3: Multiple Incoming Conduits with Incoming Bend and Drop in Invert Levels

In this example we have multiple incoming conduit. Each upstream conduit has a flow of 1m3s-1 applied to it.

Schematic 3.png
Figure 7: Example Model 3 Network Schematic
The conduits are the same shape and the same dimensions but have different invert levels as specified in the table below. All parameters for the manhole and other parts of the network are identical.

Parameter Upstream Conduit 1 Upstream Conduit 2
ID UC-2 UC-31
Upstream Invert Level (m AD) 99.8 100
Downstream Invert Level (m AD) 99.7 99.8

The resulting simulated loss values are presented in Figure 8.
Manhole Results 3.png
Figure 8: Example Model 3 Results-loss Coefficients

Example 3 - Entry Losses

This time the flow area in the manhole is 3.57m2 and 1m2 in the adjacent culvert whilst the flow is 1m3/s for Qp and 2m3s-1 for Qom. Therefore, Vm equals:Vm3.PNG
And Vp:Vp3.PNG
From this: K entry3.PNG

This matches the losses for both incoming pipes as shown in figure 8.

Example 3 - Exit Losses

A'm is 3.57m2 respectively. Therefore, Kexit:K exit3.PNG

The calculated losses match the losses calculated by the TUFLOW presented in Figure 8.

Example 3 - Outgoing Conduit Losses

In this model we have two incoming pipes, one with an 90 degree angle between the incoming and outgoing conduit and one with zero. Recall that: Ktheta.PNG

With Qf calculated as: Qf.PNG
Qp is set to 1m3s-1 and Qom to 2m3s-1. Qf is equal to 0.5m3s-1. For the incoming conduit with an angle of 90 degrees, Kθ is therefore: Ktheta2a.PNG

For the incoming conduit with an angle of 0 degrees, Kθ is therefore: Ktheta2b.PNG

We also have a drop between the incoming and outgoing pipes. Kdrop which represents losses due to this drop is calculated as follows: Kdrop 2a.PNG
and:Kdrop 2b.PNG

Therefore, Koutletpipe is: K outletpipe3.PNG

The calculated value matches that presented in figure 8 for the downstream conduit loss.