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Specific energy and flow regimes

CE 382
Dr. Huidae Cho
Department of Civil and Environmental Engineering...New Mexico State University
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1   Specific energy

Definition

  • Energy per unit weight relative to channel bottom
  • Sum of depth and velocity head
  • More formally, the height of the energy grade line above the channel bottom
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2   Physical interpretation

  • Specific energy is measured from the channel bottom
  • Elevation head $z$ is taken as zero
  • Depth term $y$
    • Comes from pressure head
    • Equals water depth for hydrostatic conditions
  • Interpretation
    • Small $y$: velocity term dominates
    • Large $y$: depth term dominates
  • Important note
    • $y$ is not elevation head
    • It represents pressure head expressed as depth
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3   From Bernoulli to specific energy

  • Choose channel bottom as datum
    • $z = 0$
  • Interpretation
    • Depth term comes from pressure head
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4   Specific energy equation

\begin{equation} E=y+\frac{\alpha V^2}{2g} \label{eq:specific-energy} \end{equation} where

  • $E$ is the specific energy,
  • $y$ is the flow depth,
  • $\alpha$ is the kinetic energy flux correction,
  • $V$ is the mean cross-sectional velocity, and
  • $g$ is the acceleration of gravity.
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5   Rectangular channel with $\alpha=1$

For a rectangular channel with $\alpha=1$, Eq. (\ref{eq:specific-energy}) can be rewritten as \begin{equation} E=y+\frac{q^2}{2gy^2} \end{equation} where $q=Q/b$ and $b$ is the channel width.

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5.1   Critical depth and specific energy

\begin{align} \frac{dE}{dy}&=1-\frac{q^2}{gy_c^3}=0\label{eq:dEdy}\\ y_c&=\left(\frac{q^2}{g}\right)^{1/3}\label{eq:yc} \end{align} \begin{equation} E_c=y_c+\frac{q^2}{2gy_c^2}=y_c+\frac{q^2}{gy_c^3}\frac{y_c}{2}=y_c+\frac{y_c}{2} =\frac{3}{2}y_c \label{eq:Ec} \end{equation} where $\dfrac{q^2}{gy_c^3}=1$ by Eq. (\ref{eq:dEdy}).

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5.2   Froude number

From Eq. (\ref{eq:dEdy}), we can obtain \begin{equation} \frac{dE}{dy}=1-\left(\frac{q}{\sqrt{gy_c^3}}\right)^2=1-\mathbf{F}^2=0 \end{equation} where the Froude number $\mathbf{F}$ is defined as \begin{equation} \mathbf{F}=\frac{q}{\sqrt{gy^3}}=\frac{q/y}{\sqrt{gy}}=\frac{Q/(by)}{\sqrt{gy}}=\frac{Q/A}{\sqrt{gy}}=\frac{V}{\sqrt{gy}} \end{equation}

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6   Specific energy diagram

specific-energy-diagram

Key features

  • Two depths for the same energy
    • Upper branch: subcritical
    • Lower branch: supercritical
  • Minimum point
    • Critical depth $y_c$
    • Critical energy $E_c$
    • Minimum energy to carry discharge

Which of $q_g$ or $q_m$ is greater or less than $q_1$? Can you explain why?

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7   Flow classification

  • $Fr < 1$
    • Subcritical
    • Deep slow flow
  • $Fr = 1$
    • Critical
  • $Fr > 1$
    • Supercritical
    • Shallow fast flow
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8   Alternate depths

  • For $E > E_c$, two possible depths
    • $y_1$ subcritical
    • $y_2$ supercritical
  • Same discharge and energy
    • Different velocity and depth
  • Transition requires energy loss
    • Example: hydraulic jump
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9   Applications

  • Channel design
    • Avoid unstable transitions
  • Control structures
    • Weirs and flumes enforce critical flow
  • Hydraulic jumps
    • Energy dissipation
  • Flow measurement
    • Critical depth relationships
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10   Numerical problem: locating points on the specific energy diagram

Given

  • Rectangular channel
  • $Q = 12 \ \text{m}^3/\text{s}$
  • $b = 3 \ \text{m}$
  • $g = 9.81 \ \text{m/s}^2$

Tasks

  • Compute the critical depth $y_c$
  • Compute the critical energy $E_c$
  • For $E = 2.50 \ \text{m}$, determine the two alternate depths
  • Identify which point is:
    • Critical
    • Subcritical
    • Supercritical
  • Sketch these three points on the specific energy diagram

Key points

  • Start with
    • $E = y + \frac{Q^2}{2 g b^2 y^2}$
  • Critical condition
    • $y_c = \left(\frac{Q^2}{g b^2}\right)^{1/3}$
  • For a given $E > E_c$
    • One larger depth is subcritical
    • One smaller depth is supercritical
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11   Solution outline: locating points on the diagram

  • Critical depth
    • $y_c = \left(\frac{12^2}{9.81 \cdot 3^2}\right)^{1/3} = \left(\frac{144}{88.29}\right)^{1/3} \approx 1.18 \ \text{m}$
  • Critical energy
    • $E_c = \frac{3}{2} y_c \approx \frac{3}{2} (1.18) = 1.77 \ \text{m}$
  • Since $E = 2.50 \ \text{m} > E_c$
    • Two alternate depths exist
  • Solve
    • $2.50 = y + \frac{12^2}{2 \cdot 9.81 \cdot 3^2 y^2}$
    • $2.50 = y + \frac{0.815}{y^2}$
  • Results
    • $y_1 \approx 2.35 \ \text{m}$ subcritical
    • $y_2 \approx 0.69 \ \text{m}$ supercritical
  • Location on the diagram
    • $(E_c, y_c) = (1.77, 1.18)$ is the minimum point
    • $(2.50, 2.35)$ lies on the upper branch
    • $(2.50, 0.69)$ lies on the lower branch
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12   From specific energy to hydraulic jump

Specific energy explains

  • Why two alternate depths can exist for the same discharge

But a hydraulic jump is not analyzed with specific energy alone

  • Because energy is lost in the jump

Instead

  • Use momentum or specific force to relate sequent depths

Hydraulic jump interpretation

  • Flow approaches as supercritical
  • Abruptly transitions to subcritical
  • Depth increases sharply
  • Energy is dissipated
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13   Hydraulic jump linkage

Before jump

  • Shallow fast flow
  • Supercritical
  • Lower branch of specific energy curve

After jump

  • Deep slow flow
  • Subcritical
  • Upper branch of specific energy curve

Across the jump

  • Discharge is conserved
  • Momentum is approximately conserved
  • Specific energy decreases

Important distinction

  • Alternate depths: same specific energy
  • Sequent depths: same momentum, different specific energy
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14   Why specific energy is still useful for hydraulic jumps

It helps explain the flow states

  • Upstream state is supercritical
  • Downstream state is subcritical

It shows that the downstream depth after a jump cannot be found by setting the same $E$

  • Because $E_1 > E_2$

It helps visualize energy loss

  • The post-jump point lies at lower energy than the pre-jump point

So

  • Specific energy is for flow-state interpretation
  • Momentum is for hydraulic jump calculation
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15   Quick comparison: alternate depth vs sequent depth

  • Alternate depths
    • Same discharge
    • Same specific energy
    • One subcritical and one supercritical
    • Read from the same specific energy curve
  • Sequent depths
    • Same discharge
    • Same momentum function
    • Connected by hydraulic jump
    • Specific energy decreases across the jump
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16   Check question

A supercritical flow enters a hydraulic jump

Which statement is correct?

  1. Specific energy is conserved across the jump
  2. Momentum is conserved but energy is lost
  3. Both momentum and energy are conserved
  4. Neither momentum nor discharge is conserved

Answer: 2. Momentum is conserved but energy is lost

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