Spacing between Electrode Calculator

✖Parallel Plate Relative Permeability of a material that describes how easily a material can be magnetized in the presence of an external magnetic field compared to a vacuum.ⓘ Parallel Plate Relative Permeability [μ_r]			+10% -10%
✖Electrode Effective Area is the area of the electrode material that is accessible to the electrolyte that is used for charge transfer or storage.ⓘ Electrode Effective Area [A]			+10% -10%
✖Specimen Capacitance is defined as the capacitance of the given specimen or of the given electronic component.ⓘ Specimen Capacitance [C_s]			+10% -10%

✖Electrode Spacing refers to the distance between two electrodes in an electrical system or device.ⓘ Spacing between Electrode [d]

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Formula

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Spacing between Electrode

Formula

`"d" = ("μ"_{"r"}*("A"*"[Permitivity-vacuum]"))/("C"_{"s"})`

Example

`"9.5m"=("9.000435"*("13m²"*"[Permitivity-vacuum]"))/("0.000109μF")`

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Spacing between Electrode Solution

STEP 0: Pre-Calculation Summary

Formula Used

Electrode Spacing = (Parallel Plate Relative Permeability*(Electrode Effective Area*[Permitivity-vacuum]))/(Specimen Capacitance)
d = (μ_r*(A*[Permitivity-vacuum]))/(C_s)
This formula uses 1 Constants, 4 Variables

Constants Used

[Permitivity-vacuum] - Permittivity of vacuum Value Taken As 8.85E-12

Variables Used

Electrode Spacing - (Measured in Meter) - Electrode Spacing refers to the distance between two electrodes in an electrical system or device.
Parallel Plate Relative Permeability - Parallel Plate Relative Permeability of a material that describes how easily a material can be magnetized in the presence of an external magnetic field compared to a vacuum.
Electrode Effective Area - (Measured in Square Meter) - Electrode Effective Area is the area of the electrode material that is accessible to the electrolyte that is used for charge transfer or storage.
Specimen Capacitance - (Measured in Farad) - Specimen Capacitance is defined as the capacitance of the given specimen or of the given electronic component.

STEP 1: Convert Input(s) to Base Unit

Parallel Plate Relative Permeability: 9.000435 --> No Conversion Required
Electrode Effective Area: 13 Square Meter --> 13 Square Meter No Conversion Required
Specimen Capacitance: 0.000109 Microfarad --> 1.09E-10 Farad (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

d = (μ_r*(A*[Permitivity-vacuum]))/(C_s) --> (9.000435*(13*[Permitivity-vacuum]))/(1.09E-10)

Evaluating ... ...

d = 9.50000042889908

STEP 3: Convert Result to Output's Unit

9.50000042889908 Meter --> No Conversion Required

FINAL ANSWER

9.50000042889908 ≈ 9.5 Meter <-- Electrode Spacing

(Calculation completed in 00.020 seconds)

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Created by Shobhit Dimri

Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat

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< 25 Instrument Dimensions Calculators

Spacing between Electrode

Go Electrode Spacing = (Parallel Plate Relative Permeability*(Electrode Effective Area*[Permitivity-vacuum]))/(Specimen Capacitance)

Hall Coefficient

Go Hall Coefficient = (Output Voltage*Thickness)/(Electric Current*Maximum Flux Density)

Length of Former

Go Former Length = Former EMF/(2*Magnetic Field*Former Breadth*Former Angular Speed)

Reluctance of Yoke's

Go Yokes Reluctance = (Magnetic Moment*Magnetic Circuits Reluctance)-Joints Reluctance

Reluctance of Joints

Go Joints Reluctance = (Magnetic Moment*Magnetic Circuits Reluctance)-Yokes Reluctance

True Magnetising Force

Go True Magnetism Force = Apparent Magnetic Force at length l+Apparent Magnetic Force at Length l/2

Length of Solenoid

Go Solenoid Length = Electric Current*Coil Turns/Magnetic Field

Apparent Magnetic Force at length l

Go Apparent Magnetic Force at length l = Coil Current at Length l*Coil Turns

Extention of Specimen

Go Specimen Extension = Magnetostriction Constant MMI*Specimen Actual Length

Hysteresis loss per unit volume

Go Hysteresis Loss per Unit Volume = Area of the hysteresis loop*Frequency

Linear velocity of Former

Go Former Linear Velocity = (Former Breadth/2)*Former Angular Speed

Area of hysteresis loop

Go Hysteresis Loop Area = Hysteresis Loss per Unit Volume/Frequency

Area of Secondary Coil

Go Secondary Coil Area = Secondary Coil Flix Linkage/Magnetic Field

Responsivity of Detector

Go Detector Responsivity = RMS Voltage/Detector RMS Incident Power

Standard Deviation for Normal Curve

Go Normal Curve Standard Deviation = 1/sqrt(Sharpness Of Curve)

Leakage Factor

Go Leakage Factor = Total Flux Per Pole/Armature Flux per Pole

Area of Cross-section of Specimen

Go Area of Cross Section = Maximum Flux Density/Magnetic Flux

Instrumentation Span

Go Instrumentation Span = Largest Reading-Smallest Reading

Damping Constant

Go Damping Constant = Damping Torque*Disc Angular Speed

Damping Torque

Go Damping Torque = Damping Constant/Disc Angular Speed

Primary Phasor

Go Primary Phasor = Transformer Ratio*Secondary Phasor

Revolution in KWh

Go Revolution = Number of Revolution/Energy Recorded

Energy Recorded

Go Energy Recorded = Number of Revolution/Revolution

Sharpness of Curve

Go Sharpness Of Curve = 1/((Normal Curve Standard Deviation)^2)

Coefficient of volumetric Expansion

Go Volumetric Expansion Coefficient = 1/Capillary Tube Length

Spacing between Electrode Formula

Electrode Spacing = (Parallel Plate Relative Permeability*(Electrode Effective Area*[Permitivity-vacuum]))/(Specimen Capacitance)
d = (μ_r*(A*[Permitivity-vacuum]))/(C_s)

Why cooling fans are required ?

Cooling fans are used to prevent the transfer of heat of the process medium to the electrical parts of the switch and maintain their temperature within suitable limits.

How to Calculate Spacing between Electrode?

Spacing between Electrode calculator uses Electrode Spacing = (Parallel Plate Relative Permeability*(Electrode Effective Area*[Permitivity-vacuum]))/(Specimen Capacitance) to calculate the Electrode Spacing, The Spacing between Electrode formula is defined as space or area between two electrodes where electrons can freely move. Electrode Spacing is denoted by d symbol.

How to calculate Spacing between Electrode using this online calculator? To use this online calculator for Spacing between Electrode, enter Parallel Plate Relative Permeability (μ_r), Electrode Effective Area (A) & Specimen Capacitance (C_s) and hit the calculate button. Here is how the Spacing between Electrode calculation can be explained with given input values -> 9.5 = (9.000435*(13*[Permitivity-vacuum]))/(1.09E-10).

FAQ

What is Spacing between Electrode?

The Spacing between Electrode formula is defined as space or area between two electrodes where electrons can freely move and is represented as d = (μ_r*(A*[Permitivity-vacuum]))/(C_s) or Electrode Spacing = (Parallel Plate Relative Permeability*(Electrode Effective Area*[Permitivity-vacuum]))/(Specimen Capacitance). Parallel Plate Relative Permeability of a material that describes how easily a material can be magnetized in the presence of an external magnetic field compared to a vacuum, Electrode Effective Area is the area of the electrode material that is accessible to the electrolyte that is used for charge transfer or storage & Specimen Capacitance is defined as the capacitance of the given specimen or of the given electronic component.

How to calculate Spacing between Electrode?

The Spacing between Electrode formula is defined as space or area between two electrodes where electrons can freely move is calculated using Electrode Spacing = (Parallel Plate Relative Permeability*(Electrode Effective Area*[Permitivity-vacuum]))/(Specimen Capacitance). To calculate Spacing between Electrode, you need Parallel Plate Relative Permeability (μ_r), Electrode Effective Area (A) & Specimen Capacitance (C_s). With our tool, you need to enter the respective value for Parallel Plate Relative Permeability, Electrode Effective Area & Specimen Capacitance 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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