FormulaDen.com

Physics Chemistry Math Chemical Engineering Civil Electrical Electronics Electronics and Instrumentation Materials Science Mechanical Production Engineering Financial Health

Dynamic viscosity of electrolyte Formula

Fx Copy

LaTeX Copy

The Dynamic Viscosity of a fluid is the measure of its resistance to flow when an external force is applied. Check FAQs

μ v = \frac{π \cdot (P 1 - P atm) \cdot h^{3}}{6 \cdot Q \cdot \ln (\frac{R 0}{R 1})}

μ_v - Dynamic Viscosity?P₁ - Pressure in Flushing Hole?P_atm - Atmospheric Pressure?h - Gap Spacing?Q - Flow Rate of the Electrolyte?R₀ - Radius of the Electrodes?R₁ - Radius of Flushing Hole?π - Archimedes' constant?

Dynamic viscosity of electrolyte Example

With values

With units

Only example

Here is how the Dynamic viscosity of electrolyte equation looks like with Values.

Here is how the Dynamic viscosity of electrolyte equation looks like with Units.

Here is how the Dynamic viscosity of electrolyte equation looks like.

10.4287 = \frac{3.1416 \cdot (11 - 10) \cdot 2^{3}}{6 \cdot 0.18 \cdot \ln (\frac{5}{4})}

10.4287P = \frac{3.1416 \cdot (11N/cm² - 10N/cm²) \cdot {2cm}^{3}}{6 \cdot 0.18m³/s \cdot \ln (\frac{5cm}{4cm})}

10.4287 = \frac{3.1416 \cdot (11 - 10) \cdot 2^{3}}{6 \cdot 0.18 \cdot \ln (\frac{5}{4})}

Tip: Use pencil ( Pencil

) icon above to edit Input Values and Units.

Calculate

Recalculate

Solution

Copy

Reset

You are here -

Home » Category

Engineering » Category

Production Engineering » Category

Unconventional machining processes » fx Dynamic viscosity of electrolyte

Dynamic viscosity of electrolyte Solution

Follow our step by step solution on how to calculate Dynamic viscosity of electrolyte?

FIRST Step Consider the formula

μ v = \frac{π \cdot (P 1 - P atm) \cdot h^{3}}{6 \cdot Q \cdot \ln (\frac{R 0}{R 1})}

Next Step Substitute values of Variables

∴

μ v = \frac{π \cdot (11N/cm² - 10N/cm²) \cdot {2cm}^{3}}{6 \cdot 0.18m³/s \cdot \ln (\frac{5cm}{4cm})}

Next Step Substitute values of Constants

∴

μ v = \frac{3.1416 \cdot (11N/cm² - 10N/cm²) \cdot {2cm}^{3}}{6 \cdot 0.18m³/s \cdot \ln (\frac{5cm}{4cm})}

Next Step Convert Units

∴

μ v = \frac{3.1416 \cdot (110000Pa - 100000Pa) \cdot {0.02m}^{3}}{6 \cdot 0.18m³/s \cdot \ln (\frac{0.05m}{0.04m})}

Next Step Prepare to Evaluate

∴

μ v = \frac{3.1416 \cdot (110000 - 100000) \cdot {0.02}^{3}}{6 \cdot 0.18 \cdot \ln (\frac{0.05}{0.04})}

Next Step Evaluate

∴

μ v = 1.04287381625874Pa*s

Next Step Convert to Output's Unit

∴

μ v = 10.4287381625874P

LAST Step Rounding Answer

∴

μ v = 10.4287P

Dynamic viscosity of electrolyte Formula Elements

Variables

Constants

Functions

Dynamic Viscosity

The Dynamic Viscosity of a fluid is the measure of its resistance to flow when an external force is applied.

Symbol: μ_v

Measurement: Dynamic ViscosityUnit: P

Note: Value should be greater than 0.

Formulas to find Dynamic Viscosity

Pressure in Flushing Hole

Pressure in Flushing Hole is the pressure in hole during EDM machining.

Symbol: P₁

Measurement: PressureUnit: N/cm²

Note: Value should be greater than 0.

Formulas to find Pressure in Flushing Hole

Atmospheric Pressure

Atmospheric pressure, also known as barometric pressure, is the pressure within the atmosphere of Earth.

Symbol: P_atm

Measurement: PressureUnit: N/cm²

Note: Value can be positive or negative.

Formulas to find Atmospheric Pressure

Gap Spacing

Gap spacing is the width of distance between electrode and work during EDM.

Symbol: h

Measurement: LengthUnit: cm

Note: Value should be greater than 0.

Formulas to find Gap Spacing

Flow Rate of the Electrolyte

Flow rate of the electrolyte is the flow rate of the electrolyte used in EDM.

Symbol: Q

Measurement: Volumetric Flow RateUnit: m³/s

Note: Value can be positive or negative.

Formulas to find Flow Rate of the Electrolyte

Radius of the Electrodes

Radius of the electrodes is defined as the radius of the electrode used for unconventional machining by EDM.

Symbol: R₀

Measurement: LengthUnit: cm

Note: Value can be positive or negative.

Formulas to find Radius of the Electrodes

Radius of Flushing Hole

Radius of flushing hole is the radius of flushing hole in EDM.

Symbol: R₁

Measurement: LengthUnit: cm

Note: Value should be greater than 0.

Formulas to find Radius of Flushing Hole

Archimedes' constant

Archimedes' constant is a mathematical constant that represents the ratio of the circumference of a circle to its diameter.

Symbol: π

Value: 3.14159265358979323846264338327950288

The natural logarithm, also known as the logarithm to the base e, is the inverse function of the natural exponential function.

Syntax: ln(Number)

Other formulas in Flow rate of the electrolyte category

Go Flow rate of electrolyte

Q = \frac{π \cdot (P 1 - P atm) \cdot h^{3}}{6 \cdot μ v \cdot \ln (\frac{R 0}{R 1})}

Go Gap spacing

h = {(\frac{Q \cdot 6 \cdot μ v \cdot \ln (\frac{R 0}{R 1})}{π \cdot (P 1 - P atm)})}^{\frac{1}{3}}

How to Evaluate Dynamic viscosity of electrolyte?

Dynamic viscosity of electrolyte evaluator uses Dynamic Viscosity = (pi*(Pressure in Flushing Hole-Atmospheric Pressure)*Gap Spacing^3)/(6*Flow Rate of the Electrolyte*ln(Radius of the Electrodes/Radius of Flushing Hole)) to evaluate the Dynamic Viscosity, The Dynamic viscosity of electrolyte formula is defined as the resistance offered by various layers of fluid used as electrolyte in EDM. Dynamic Viscosity is denoted by μ_v symbol.

How to evaluate Dynamic viscosity of electrolyte using this online evaluator? To use this online evaluator for Dynamic viscosity of electrolyte, enter Pressure in Flushing Hole (P₁), Atmospheric Pressure (P_atm), Gap Spacing (h), Flow Rate of the Electrolyte (Q), Radius of the Electrodes (R₀) & Radius of Flushing Hole (R₁) and hit the calculate button.

FAQs on Dynamic viscosity of electrolyte

What is the formula to find Dynamic viscosity of electrolyte?

The formula of Dynamic viscosity of electrolyte is expressed as Dynamic Viscosity = (pi*(Pressure in Flushing Hole-Atmospheric Pressure)*Gap Spacing^3)/(6*Flow Rate of the Electrolyte*ln(Radius of the Electrodes/Radius of Flushing Hole)). Here is an example- 6.257243 = (pi*(110000-100000)*0.02^3)/(6*0.18*ln(0.05/0.04)).

How to calculate Dynamic viscosity of electrolyte?

With Pressure in Flushing Hole (P₁), Atmospheric Pressure (P_atm), Gap Spacing (h), Flow Rate of the Electrolyte (Q), Radius of the Electrodes (R₀) & Radius of Flushing Hole (R₁) we can find Dynamic viscosity of electrolyte using the formula - Dynamic Viscosity = (pi*(Pressure in Flushing Hole-Atmospheric Pressure)*Gap Spacing^3)/(6*Flow Rate of the Electrolyte*ln(Radius of the Electrodes/Radius of Flushing Hole)). This formula also uses Archimedes' constant and Natural Logarithm (ln) function(s).

Can the Dynamic viscosity of electrolyte be negative?

No, the Dynamic viscosity of electrolyte, measured in Dynamic Viscosity cannot be negative.

Which unit is used to measure Dynamic viscosity of electrolyte?

Dynamic viscosity of electrolyte is usually measured using the Poise[P] for Dynamic Viscosity. Pascal Second[P], Newton Second per Square Meter[P], Millinewton Second per Square Meter[P] are the few other units in which Dynamic viscosity of electrolyte can be measured.

Let Others Know

✖

Facebook

Twitter

Copied!

Dynamic viscosity of electrolyte Formula

Dynamic viscosity of electrolyte Example

Dynamic viscosity of electrolyte Solution

Dynamic viscosity of electrolyte Formula Elements

Other formulas in Flow rate of the electrolyte category

How to Evaluate Dynamic viscosity of electrolyte?

FAQs on Dynamic viscosity of electrolyte

Variable Name