Loss Coefficient for Various Fitting Calculator

✖Head Loss due to Friction is the reduction in fluid pressure energy as it flows through a conduit, caused by friction between the fluid and the conduit walls.ⓘ Head Loss due to Friction [H_f]			+10% -10%
✖Fluid Average Velocity is the mean speed at which fluid particles travel through a cross-section of a conduit, influencing flow rate and dynamics, typically measured in meters per second (m/s).ⓘ Fluid Average Velocity [V_avg]			+10% -10%

✖Head Loss Coefficient quantifies energy loss due to friction or obstructions in fluid flow, affecting pressure drop, calculated from experimental data or theoretical models in fluid dynamics.ⓘ Loss Coefficient for Various Fitting [K]

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Formula

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Loss Coefficient for Various Fitting

Formula

`"K" = ("H"_{"f"}*2*"[g]")/("V"_{"avg"}^2)`

Example

`"22.14442"=("12.37m"*2*"[g]")/(("3.31m/s")^2)`

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Loss Coefficient for Various Fitting Solution

STEP 0: Pre-Calculation Summary

Formula Used

Head Loss Coefficient = (Head Loss due to Friction*2*[g])/(Fluid Average Velocity^2)
K = (H_f*2*[g])/(V_avg^2)
This formula uses 1 Constants, 3 Variables

Constants Used

[g] - Gravitational acceleration on Earth Value Taken As 9.80665

Variables Used

Head Loss Coefficient - Head Loss Coefficient quantifies energy loss due to friction or obstructions in fluid flow, affecting pressure drop, calculated from experimental data or theoretical models in fluid dynamics.
Head Loss due to Friction - (Measured in Meter) - Head Loss due to Friction is the reduction in fluid pressure energy as it flows through a conduit, caused by friction between the fluid and the conduit walls.
Fluid Average Velocity - (Measured in Meter per Second) - Fluid Average Velocity is the mean speed at which fluid particles travel through a cross-section of a conduit, influencing flow rate and dynamics, typically measured in meters per second (m/s).

STEP 1: Convert Input(s) to Base Unit

Head Loss due to Friction: 12.37 Meter --> 12.37 Meter No Conversion Required
Fluid Average Velocity: 3.31 Meter per Second --> 3.31 Meter per Second No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

K = (H_f*2*[g])/(V_avg^2) --> (12.37*2*[g])/(3.31^2)

Evaluating ... ...

K = 22.1444237456759

STEP 3: Convert Result to Output's Unit

22.1444237456759 --> No Conversion Required

FINAL ANSWER

22.1444237456759 ≈ 22.14442 <-- Head Loss Coefficient

(Calculation completed in 00.004 seconds)

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Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat

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< 16 Flow Measurement Calculators

Drag Coefficient of Pipe

Go Drag Coefficient = (Force Flow*2*[g])/(Specific Weight Fluid Flow*Pipe Cross Sectional Area*Fluid Velocity)

Length of Pipe

Go Pipe Length = (2*Pipe Diameter*Head Loss due to Friction*[g])/(Friction Factor*Fluid Average Velocity^2)

Pipe Diameter

Go Pipe Diameter = (Friction Factor*Pipe Length*Fluid Average Velocity^2)/(2*Head Loss due to Friction*[g])

Head Loss

Go Head Loss due to Friction = (Friction Factor*Pipe Length*Fluid Average Velocity^2)/(2*Pipe Diameter*[g])

Density of Liquid

Go Fluid Density = (Reynolds Number*Absolute Fluid Viscosity)/(Fluid Velocity*Pipe Diameter)

Reynolds number of fluid flowing in Pipe

Go Reynolds Number = (Fluid Velocity*Pipe Diameter*Fluid Density)/Absolute Fluid Viscosity

Absolute Viscosity

Go Absolute Fluid Viscosity = (Fluid Velocity*Pipe Diameter*Fluid Density)/Reynolds Number

Loss Coefficient for Various Fitting

Go Head Loss Coefficient = (Head Loss due to Friction*2*[g])/(Fluid Average Velocity^2)

Head Loss Due to Fitting

Go Head Loss due to Friction = (Head Loss Coefficient*Fluid Average Velocity^2)/(2*[g])

Weight of Material on Length of Weighing Platform

Go Material Weight Flow = (Mass Flow Rate*Weighing Platform Length)/Conveyer Belt Speed

Length of weighing platform

Go Weighing Platform Length = (Material Weight Flow*Conveyer Belt Speed)/Mass Flow Rate

Speed of Conveyor Belt

Go Conveyer Belt Speed = (Weighing Platform Length*Mass Flow Rate)/Material Weight Flow

Average Velocity of Fluid

Go Fluid Average Velocity = Volume Flow Rate/Pipe Cross Sectional Area

Flow Rate

Go Volume Flow Rate = Pipe Cross Sectional Area*Fluid Average Velocity

Volume Flow Rate

Go Volume Flow Rate = Mass Flow Rate/Material Density

Mass Flow Rate

Go Mass Flow Rate = Material Density*Volume Flow Rate

Loss Coefficient for Various Fitting Formula

Head Loss Coefficient = (Head Loss due to Friction*2*[g])/(Fluid Average Velocity^2)
K = (H_f*2*[g])/(V_avg^2)

What causes head loss in pipe flow?

The head, pressure, or energy (they are the same) lost by water flowing in a pipe or channel as a result of turbulence caused by the velocity of the flowing water and the roughness of the pipe, channel walls, or fittings. Water flowing in a pipe loses its head as a result of friction losses.

How to Calculate Loss Coefficient for Various Fitting?

Loss Coefficient for Various Fitting calculator uses Head Loss Coefficient = (Head Loss due to Friction*2*[g])/(Fluid Average Velocity^2) to calculate the Head Loss Coefficient, The Loss Coefficient for Various Fitting formula is defined as the dimensionless number (characteristic coefficient) to calculate the head loss (HL) (see Pressure loss): v Characteristic flow velocity in the relevant hydraulic component (usually the flow velocity in the. cross-section of the connection downstream of the component). Head Loss Coefficient is denoted by K symbol.

How to calculate Loss Coefficient for Various Fitting using this online calculator? To use this online calculator for Loss Coefficient for Various Fitting, enter Head Loss due to Friction (H_f) & Fluid Average Velocity (V_avg) and hit the calculate button. Here is how the Loss Coefficient for Various Fitting calculation can be explained with given input values -> 22.14442 = (12.37*2*[g])/(3.31^2).

FAQ

What is Loss Coefficient for Various Fitting?

The Loss Coefficient for Various Fitting formula is defined as the dimensionless number (characteristic coefficient) to calculate the head loss (HL) (see Pressure loss): v Characteristic flow velocity in the relevant hydraulic component (usually the flow velocity in the. cross-section of the connection downstream of the component) and is represented as K = (H_f*2*[g])/(V_avg^2) or Head Loss Coefficient = (Head Loss due to Friction*2*[g])/(Fluid Average Velocity^2). Head Loss due to Friction is the reduction in fluid pressure energy as it flows through a conduit, caused by friction between the fluid and the conduit walls & Fluid Average Velocity is the mean speed at which fluid particles travel through a cross-section of a conduit, influencing flow rate and dynamics, typically measured in meters per second (m/s).

How to calculate Loss Coefficient for Various Fitting?

The Loss Coefficient for Various Fitting formula is defined as the dimensionless number (characteristic coefficient) to calculate the head loss (HL) (see Pressure loss): v Characteristic flow velocity in the relevant hydraulic component (usually the flow velocity in the. cross-section of the connection downstream of the component) is calculated using Head Loss Coefficient = (Head Loss due to Friction*2*[g])/(Fluid Average Velocity^2). To calculate Loss Coefficient for Various Fitting, you need Head Loss due to Friction (H_f) & Fluid Average Velocity (V_avg). With our tool, you need to enter the respective value for Head Loss due to Friction & Fluid Average Velocity and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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