Length when Coefficient of Permeability at Permeameter Experiment is Considered Calculator

✖Constant Head Difference is the difference between the Points separated by a small distance dl.ⓘ Constant Head Difference [ΔH]			+10% -10%
✖Cross-Sectional Area is the product of width multiplied by average water depth.ⓘ Cross-Sectional Area [A]			+10% -10%
✖The coefficient of Permeability at the temperature describes how easily a liquid will move through the porous medium.ⓘ Coefficient of Permeability at the temperature [K]			+10% -10%
✖Discharge is the volumetric flow rate of water that is transported through a given cross-sectional area. It includes any suspended solids, dissolved chemicals, or biologic material.ⓘ Discharge [Q]			+10% -10%

✖Length is the measurement or extent of something from end to end.ⓘ Length when Coefficient of Permeability at Permeameter Experiment is Considered [L]

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Formula

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Length when Coefficient of Permeability at Permeameter Experiment is Considered

Formula

`"L" = ("ΔH"*"A"*"K")/"Q"`

Example

`"4m"=("2"*"100m²"*"6cm/s")/"3.0m³/s"`

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Length when Coefficient of Permeability at Permeameter Experiment is Considered Solution

STEP 0: Pre-Calculation Summary

Formula Used

Length = (Constant Head Difference*Cross-Sectional Area*Coefficient of Permeability at the temperature)/Discharge
L = (ΔH*A*K)/Q
This formula uses 5 Variables

Variables Used

Length - (Measured in Meter) - Length is the measurement or extent of something from end to end.
Constant Head Difference - Constant Head Difference is the difference between the Points separated by a small distance dl.
Cross-Sectional Area - (Measured in Square Meter) - Cross-Sectional Area is the product of width multiplied by average water depth.
Coefficient of Permeability at the temperature - (Measured in Meter per Second) - The coefficient of Permeability at the temperature describes how easily a liquid will move through the porous medium.
Discharge - (Measured in Cubic Meter per Second) - Discharge is the volumetric flow rate of water that is transported through a given cross-sectional area. It includes any suspended solids, dissolved chemicals, or biologic material.

STEP 1: Convert Input(s) to Base Unit

Constant Head Difference: 2 --> No Conversion Required
Cross-Sectional Area: 100 Square Meter --> 100 Square Meter No Conversion Required
Coefficient of Permeability at the temperature: 6 Centimeter per Second --> 0.06 Meter per Second (Check conversion here)
Discharge: 3 Cubic Meter per Second --> 3 Cubic Meter per Second No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

L = (ΔH*A*K)/Q --> (2*100*0.06)/3

Evaluating ... ...

L = 4

STEP 3: Convert Result to Output's Unit

4 Meter --> No Conversion Required

FINAL ANSWER

4 Meter <-- Length

(Calculation completed in 00.004 seconds)

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< 21 Coefficient of Permeability Calculators

Hagen Poiseuille flow or mean particle size of porous medium laminar flow through conduit

Go Mean Particle Size of the Porous Medium = sqrt((Coefficient of Permeability (Hagen-Poiseuille)*Dynamic Viscosity of the Fluid)/(Shape Factor*(Unit Weight of Fluid/1000)))

Dynamic viscosity of fluid of laminar flow through conduit or Hagen Poiseuille flow

Go Dynamic Viscosity of the Fluid = (Shape Factor*Mean Particle Size of the Porous Medium^2)*((Unit Weight of Fluid/1000)/Coefficient of Permeability (Hagen-Poiseuille))

Coefficient of permeability from analogy of laminar flow (Hagen Poiseuille flow)

Go Coefficient of Permeability (Hagen-Poiseuille) = Shape Factor*(Mean Particle Size of the Porous Medium^2)*(Unit Weight of Fluid/1000)/Dynamic Viscosity of the Fluid

Coefficient of permeability at any temperature t for standard value of coefficient of permeability

Go Coefficient of Permeability at any Temperature t = (Standard Coefficient of Permeability at 20°C*Kinematic Viscosity at 20° C)/Kinematic Viscosity at t° C

Kinematic Viscosity at 20 degree Celsius for standard value of coefficient of permeability

Go Kinematic Viscosity at 20° C = (Coefficient of Permeability at any Temperature t*Kinematic Viscosity at t° C)/Standard Coefficient of Permeability at 20°C

Kinematic Viscosity for standard value of coefficient of permeability

Go Kinematic Viscosity at t° C = (Standard Coefficient of Permeability at 20°C*Kinematic Viscosity at 20° C)/Coefficient of Permeability at any Temperature t

Standard value of coefficient of permeability

Go Standard Coefficient of Permeability at 20°C = Coefficient of Permeability at any Temperature t*(Kinematic Viscosity at t° C/Kinematic Viscosity at 20° C)

Coefficient of permeability at temperature of permeameter experiment

Go Coefficient of Permeability at the temperature = (Discharge/Cross-Sectional Area)*(1/(Constant Head Difference/Length))

Cross sectional area when coefficient of permeability at permeameter experiment is considered

Go Cross-Sectional Area = Discharge/(Coefficient of Permeability at the temperature*(Constant Head Difference/Length))

Discharge when Coefficient of Permeability at Permeameter Experiment is Considered

Go Discharge = Coefficient of Permeability at the temperature*Cross-Sectional Area*(Constant Head Difference/Length)

Length when Coefficient of Permeability at Permeameter Experiment is Considered

Go Length = (Constant Head Difference*Cross-Sectional Area*Coefficient of Permeability at the temperature)/Discharge

Coefficient of Permeability when Specific or Intrinsic Permeability is Considered

Go Coefficient of Permeability at the temperature = Intrinsic Permeability*((Unit Weight of Fluid/1000)/Dynamic Viscosity of the Fluid)

Specific or Intrinsic Permeability when Coefficient of Permeability is Considered

Go Intrinsic Permeability = (Coefficient of Permeability at the temperature*Dynamic Viscosity of the Fluid)/(Unit Weight of Fluid/1000)

Specific or Intrinsic Permeability when Dynamic Viscosity is Considered

Go Intrinsic Permeability = (Coefficient of Permeability at the temperature*Dynamic Viscosity of the Fluid)/(Unit Weight of Fluid/1000)

Dynamic Viscosity when Specific or Intrinsic Permeability is Considered

Go Dynamic Viscosity of the Fluid = Intrinsic Permeability*((Unit Weight of Fluid/1000)/Coefficient of Permeability at the temperature)

Kinematic Viscosity when Specific or Intrinsic Permeability is Considered

Go Kinematic Viscosity = (Intrinsic Permeability*Acceleration due to Gravity)/Coefficient of Permeability

Equation for Specific or Intrinsic Permeability

Go Intrinsic Permeability = Shape Factor*Mean Particle Size of the Porous Medium^2

Kinematic Viscosity and Dynamic Viscosity Relation

Go Kinematic Viscosity = Dynamic Viscosity of the Fluid/Density of Fluid

Unit weight of fluid

Go Unit Weight of Fluid = Density of Fluid*Acceleration due to Gravity

Coefficient of Permeability when Transmissibility is Considered

Go Coefficient of Permeability = Transmissibility/Aquifer Thickness

Equivalent permeability when transmissivity of aquifer is considered

Go Equivalent Permeability = Transmissivity/Aquifer Thickness

Length when Coefficient of Permeability at Permeameter Experiment is Considered Formula

Length = (Constant Head Difference*Cross-Sectional Area*Coefficient of Permeability at the temperature)/Discharge
L = (ΔH*A*K)/Q

What is Aquifer Transmissivity?

Transmissivity describes the ability of the aquifer to transmit groundwater throughout its entire saturated thickness. Transmissivity is measured as the rate at which groundwater can flow through an aquifer section of unit width under a unit hydraulic gradient.

How to Calculate Length when Coefficient of Permeability at Permeameter Experiment is Considered?

Length when Coefficient of Permeability at Permeameter Experiment is Considered calculator uses Length = (Constant Head Difference*Cross-Sectional Area*Coefficient of Permeability at the temperature)/Discharge to calculate the Length, The Length when Coefficient of Permeability at Permeameter Experiment is Considered is defined as the effective length of the cross-sectional area or catchment area of consideration. Length is denoted by L symbol.

How to calculate Length when Coefficient of Permeability at Permeameter Experiment is Considered using this online calculator? To use this online calculator for Length when Coefficient of Permeability at Permeameter Experiment is Considered, enter Constant Head Difference (ΔH), Cross-Sectional Area (A), Coefficient of Permeability at the temperature (K) & Discharge (Q) and hit the calculate button. Here is how the Length when Coefficient of Permeability at Permeameter Experiment is Considered calculation can be explained with given input values -> 4 = (2*100*0.06)/3.

FAQ

What is Length when Coefficient of Permeability at Permeameter Experiment is Considered?

The Length when Coefficient of Permeability at Permeameter Experiment is Considered is defined as the effective length of the cross-sectional area or catchment area of consideration and is represented as L = (ΔH*A*K)/Q or Length = (Constant Head Difference*Cross-Sectional Area*Coefficient of Permeability at the temperature)/Discharge. Constant Head Difference is the difference between the Points separated by a small distance dl, Cross-Sectional Area is the product of width multiplied by average water depth, The coefficient of Permeability at the temperature describes how easily a liquid will move through the porous medium & Discharge is the volumetric flow rate of water that is transported through a given cross-sectional area. It includes any suspended solids, dissolved chemicals, or biologic material.

How to calculate Length when Coefficient of Permeability at Permeameter Experiment is Considered?

The Length when Coefficient of Permeability at Permeameter Experiment is Considered is defined as the effective length of the cross-sectional area or catchment area of consideration is calculated using Length = (Constant Head Difference*Cross-Sectional Area*Coefficient of Permeability at the temperature)/Discharge. To calculate Length when Coefficient of Permeability at Permeameter Experiment is Considered, you need Constant Head Difference (ΔH), Cross-Sectional Area (A), Coefficient of Permeability at the temperature (K) & Discharge (Q). With our tool, you need to enter the respective value for Constant Head Difference, Cross-Sectional Area, Coefficient of Permeability at the temperature & Discharge 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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