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Mitra's Hyperbolic Transition when Water Depth remains Constant Formula

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Bed width at any distance x from flumed section. Check FAQs

B x = \frac{B n \cdot B f \cdot L f}{(L f \cdot B n) - ((B n - B f) \cdot x)}

B_x - Bed Width at Any Distance X from Flumed Section?B_n - Bed Width of Normal Channel Section?B_f - Bed Width of Flumed Channel Section?L_f - Length of Transition?x - Bed Width of Distance X?

Mitra's Hyperbolic Transition when Water Depth remains Constant Example

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Here is how the Mitra's Hyperbolic Transition when Water Depth remains Constant equation looks like with Values.

Here is how the Mitra's Hyperbolic Transition when Water Depth remains Constant equation looks like with Units.

Here is how the Mitra's Hyperbolic Transition when Water Depth remains Constant equation looks like.

11.3636 = \frac{25 \cdot 10 \cdot 15}{(15 \cdot 25) - ((25 - 10) \cdot 3)}

11.3636 = \frac{25m \cdot 10m \cdot 15m}{(15m \cdot 25m) - ((25m - 10m) \cdot 3m)}

11.3636 = \frac{25 \cdot 10 \cdot 15}{(15 \cdot 25) - ((25 - 10) \cdot 3)}

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Mitra's Hyperbolic Transition when Water Depth remains Constant Solution

Follow our step by step solution on how to calculate Mitra's Hyperbolic Transition when Water Depth remains Constant?

FIRST Step Consider the formula

B x = \frac{B n \cdot B f \cdot L f}{(L f \cdot B n) - ((B n - B f) \cdot x)}

Next Step Substitute values of Variables

∴

B x = \frac{25m \cdot 10m \cdot 15m}{(15m \cdot 25m) - ((25m - 10m) \cdot 3m)}

Next Step Prepare to Evaluate

∴

B x = \frac{25 \cdot 10 \cdot 15}{(15 \cdot 25) - ((25 - 10) \cdot 3)}

Next Step Evaluate

∴

B x = 11.3636363636364

LAST Step Rounding Answer

∴

B x = 11.3636

Mitra's Hyperbolic Transition when Water Depth remains Constant Formula Elements

Variables

Bed Width at Any Distance X from Flumed Section

Bed width at any distance x from flumed section.

Symbol: B_x

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Bed Width at Any Distance X from Flumed Section

Bed Width of Normal Channel Section

Bed width of normal channel section.

Symbol: B_n

Measurement: LengthUnit: m

Note: Value can be positive or negative.

Formulas to find Bed Width of Normal Channel Section

Bed Width of Flumed Channel Section

Bed width of flumed channel section.

Symbol: B_f

Measurement: LengthUnit: m

Note: Value should be greater than 0.

Formulas to find Bed Width of Flumed Channel Section

Length of Transition

Length of transition is the distance required in transitioning the road from normal to full super elevation.

Symbol: L_f

Measurement: LengthUnit: m

Note: Value should be greater than 0.

Formulas to find Length of Transition

Bed Width of Distance X

Bed width of distance x. the physical confine of the normal water flow.

Symbol: x

Measurement: LengthUnit: m

Note: Value can be positive or negative.

Formulas to find Bed Width of Distance X

Other formulas in Methods Used for Designing the Channel Transitions category

Go Chaturvedi's Semi Cubical Parabolic Transition when Water Depth remains Contant

x = \frac{L f \cdot {B c}^{\frac{3}{2}}}{{B c}^{\frac{3}{2}} - {B f}^{\frac{3}{2}}} \cdot (1 - {(\frac{B f}{B x})}^{\frac{3}{2}})

How to Evaluate Mitra's Hyperbolic Transition when Water Depth remains Constant?

Mitra's Hyperbolic Transition when Water Depth remains Constant evaluator uses Bed Width at Any Distance X from Flumed Section = (Bed Width of Normal Channel Section*Bed Width of Flumed Channel Section*Length of Transition)/((Length of Transition*Bed Width of Normal Channel Section)-((Bed Width of Normal Channel Section-Bed Width of Flumed Channel Section)*Bed Width of Distance X)) to evaluate the Bed Width at Any Distance X from Flumed Section, The Mitra's Hyperbolic Transition when Water Depth remains Constant formula is defined as bed width from the flumed section. Bed Width at Any Distance X from Flumed Section is denoted by B_x symbol.

How to evaluate Mitra's Hyperbolic Transition when Water Depth remains Constant using this online evaluator? To use this online evaluator for Mitra's Hyperbolic Transition when Water Depth remains Constant, enter Bed Width of Normal Channel Section (B_n), Bed Width of Flumed Channel Section (B_f), Length of Transition (L_f) & Bed Width of Distance X (x) and hit the calculate button.

FAQs on Mitra's Hyperbolic Transition when Water Depth remains Constant

What is the formula to find Mitra's Hyperbolic Transition when Water Depth remains Constant?

The formula of Mitra's Hyperbolic Transition when Water Depth remains Constant is expressed as Bed Width at Any Distance X from Flumed Section = (Bed Width of Normal Channel Section*Bed Width of Flumed Channel Section*Length of Transition)/((Length of Transition*Bed Width of Normal Channel Section)-((Bed Width of Normal Channel Section-Bed Width of Flumed Channel Section)*Bed Width of Distance X)). Here is an example- 11.36364 = (25*10*15)/((15*25)-((25-10)*3)).

How to calculate Mitra's Hyperbolic Transition when Water Depth remains Constant?

With Bed Width of Normal Channel Section (B_n), Bed Width of Flumed Channel Section (B_f), Length of Transition (L_f) & Bed Width of Distance X (x) we can find Mitra's Hyperbolic Transition when Water Depth remains Constant using the formula - Bed Width at Any Distance X from Flumed Section = (Bed Width of Normal Channel Section*Bed Width of Flumed Channel Section*Length of Transition)/((Length of Transition*Bed Width of Normal Channel Section)-((Bed Width of Normal Channel Section-Bed Width of Flumed Channel Section)*Bed Width of Distance X)).

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Mitra's Hyperbolic Transition when Water Depth remains Constant Formula

Mitra's Hyperbolic Transition when Water Depth remains Constant Example

Mitra's Hyperbolic Transition when Water Depth remains Constant Solution

Mitra's Hyperbolic Transition when Water Depth remains Constant Formula Elements

Other formulas in Methods Used for Designing the Channel Transitions category

How to Evaluate Mitra's Hyperbolic Transition when Water Depth remains Constant?

FAQs on Mitra's Hyperbolic Transition when Water Depth remains Constant

Variable Name