HY8:Tumbling Flow: Difference between revisions

From XMS Wiki
Jump to navigationJump to search
 
(11 intermediate revisions by the same user not shown)
Line 1: Line 1:
The tumbling flow dissipator type can be used for either box culverts or circular culverts. Variables for these [[HY8:Energy Dissipators|energy dissipators]] are described below.
==Tumbling Flow in Box Culverts==
==Tumbling Flow in Box Culverts==
The input variables required for this calculation is the following:
The input variables required for this calculation is the following:
Line 8: Line 9:
The following figures show two configurations of tumbling flow dissipators.
The following figures show two configurations of tumbling flow dissipators.


[[Image:HY8image11.jpg]]
[[Image:HY8image11.jpg|thumb|none|500 px|Figure 1]]


Variables from the figure
Variables from Figure 1:


* L — Length from beginning of one roughness element  to the beginning of the next roughness element.
* L — Length from beginning of one roughness element  to the beginning of the next roughness element.
Line 19: Line 20:
* y<sub>n</sub> &mdash; Tailwater depth
* y<sub>n</sub> &mdash; Tailwater depth


[[Image:HY8image12.jpg]]
[[Image:HY8image12.jpg|thumb|none|375 px|Figure 2]]


Variables from the figure
Variables from Figure 2:


* L<sub>1</sub> &mdash; Length from beginning of one roughness element to the beginning of the next roughness element.
* L<sub>1</sub> &mdash; Length from beginning of one roughness element to the beginning of the next roughness element.
Line 31: Line 32:


==Tumbling Flow in Circular Culverts==
==Tumbling Flow in Circular Culverts==
The only input variable required for this calculation is the following:
* Diameter of enlarged culvert
The following figures show implementations of tumbling flow within circular culverts along with the variables used to design the energy dissipator.
[[Image:HY8fig7-1.jpg|thumb|none|450 px|Figure 1]]
Variables from Figure 1:
* D &mdash; Diameter of original culvert
* V<sub>n</sub> &mdash; Tailwater velocity
* y<sub>n</sub> &mdash; Tailwater depth
* L &mdash; Length from beginning of one roughness element  to the beginning of the next roughness element.
* h &mdash; Height of roughness element
* h<sub>1</sub> &mdash; length from top of roughness element to enlarged culvert ceiling
* h<sub>2</sub> &mdash; height of splash shield on enlarged culvert ceiling.
* h<sub>3</sub> &mdash; rise of enlarged culvert.
[[Image:HY8fig7-4.jpg|thumb|none|550 px|Figure 2]]
Variables from Figure 2:
* D &mdash; Diameter of original culvert
* D<sub>1</sub> &mdash; Diameter of enlarged culvert
* D<sub>i</sub> &mdash; Diameter of roughened section
* h &mdash; Height of roughness element
* L &mdash; Length from beginning of one roughness element  to the beginning of the next roughness element.
[[Image:HY8image6.jpg|thumb|none|300 px|Figure 3]]
Variables from Figure 3:
* D &mdash; Diameter of original culvert
* T &mdash; Water surface width at critical flow condition
* y &mdash; Depth of flow
{{HY8Main}}
[[Category:Energy Dissipators|T]]

Latest revision as of 15:59, 1 December 2016

The tumbling flow dissipator type can be used for either box culverts or circular culverts. Variables for these energy dissipators are described below.

Tumbling Flow in Box Culverts

The input variables required for this calculation is the following:

Roughness Spacing to Height Ratio — The user must select a value of either 8.5 or 10 for the ratio of roughness element spacing divided by roughness element height. If after calculations the flow through the roughened section of the culvert impacts on the culvert roof, then the minimum enlarged section height needed to correct this problem will be given and the user will be prompted to enter a value equal to or larger than this minimum value.

Height, which must be equal to or greater than the height of the culvert.

The following figures show two configurations of tumbling flow dissipators.

Figure 1

Variables from Figure 1:

  • L — Length from beginning of one roughness element to the beginning of the next roughness element.
  • h — Height of roughness element
  • h1 — Distance from top of dissipator to ceiling of culvert
  • h2 — Height of splash shield on ceiling of culvert
  • h3 — Culvert rise
  • yn — Tailwater depth
Figure 2

Variables from Figure 2:

  • L1 — Length from beginning of one roughness element to the beginning of the next roughness element.
  • LT — Transition Length
  • hi — Height of roughness element
  • yc — Critical depth
  • θ — slope of the culvert bottom expressed in degrees
  • φ — jet angle, taken as 45 degrees

Tumbling Flow in Circular Culverts

The only input variable required for this calculation is the following:

  • Diameter of enlarged culvert

The following figures show implementations of tumbling flow within circular culverts along with the variables used to design the energy dissipator.

Figure 1

Variables from Figure 1:

  • D — Diameter of original culvert
  • Vn — Tailwater velocity
  • yn — Tailwater depth
  • L — Length from beginning of one roughness element to the beginning of the next roughness element.
  • h — Height of roughness element
  • h1 — length from top of roughness element to enlarged culvert ceiling
  • h2 — height of splash shield on enlarged culvert ceiling.
  • h3 — rise of enlarged culvert.
Figure 2

Variables from Figure 2:

  • D — Diameter of original culvert
  • D1 — Diameter of enlarged culvert
  • Di — Diameter of roughened section
  • h — Height of roughness element
  • L — Length from beginning of one roughness element to the beginning of the next roughness element.
Figure 3

Variables from Figure 3:

  • D — Diameter of original culvert
  • T — Water surface width at critical flow condition
  • y — Depth of flow