Current Supplied for Electrolysis given Specific Resistivity of Electrolyte Calculator

✖Area of Penetration is area of penetration of electrons.ⓘ Area of Penetration [A]			+10% -10%
✖Supply Voltage is the voltage required to charge a given device within a given time.ⓘ Supply Voltage [V_s]			+10% -10%
✖The Gap between Tool and Work Surface is the stretch of the distance between Tool and Work Surface during Electrochemical Machining.ⓘ Gap Between Tool and Work Surface [h]			+10% -10%
✖Specific Resistance of the electrolyte is the measure of how strongly it opposes the flow of current through them.ⓘ Specific Resistance of The Electrolyte [r_e]			+10% -10%

✖Electric current is the rate of flow of electric charge through a circuit, measured in amperes.ⓘ Current Supplied for Electrolysis given Specific Resistivity of Electrolyte [I]

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Formula

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Current Supplied for Electrolysis given Specific Resistivity of Electrolyte

Formula

`"I" = "A"*"V"_{"s"}/("h"*"r"_{"e"})`

Example

`"1000.059A"="7.6cm²"*"9.869V"/("0.25mm"*"3Ω*cm")`

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Current Supplied for Electrolysis given Specific Resistivity of Electrolyte Solution

STEP 0: Pre-Calculation Summary

Formula Used

Electric Current = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Specific Resistance of The Electrolyte)
I = A*V_s/(h*r_e)
This formula uses 5 Variables

Variables Used

Electric Current - (Measured in Ampere) - Electric current is the rate of flow of electric charge through a circuit, measured in amperes.
Area of Penetration - (Measured in Square Meter) - Area of Penetration is area of penetration of electrons.
Supply Voltage - (Measured in Volt) - Supply Voltage is the voltage required to charge a given device within a given time.
Gap Between Tool and Work Surface - (Measured in Meter) - The Gap between Tool and Work Surface is the stretch of the distance between Tool and Work Surface during Electrochemical Machining.
Specific Resistance of The Electrolyte - (Measured in Ohm Meter) - Specific Resistance of the electrolyte is the measure of how strongly it opposes the flow of current through them.

STEP 1: Convert Input(s) to Base Unit

Area of Penetration: 7.6 Square Centimeter --> 0.00076 Square Meter (Check conversion here)
Supply Voltage: 9.869 Volt --> 9.869 Volt No Conversion Required
Gap Between Tool and Work Surface: 0.25 Millimeter --> 0.00025 Meter (Check conversion here)
Specific Resistance of The Electrolyte: 3 Ohm Centimeter --> 0.03 Ohm Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

I = A*V_s/(h*r_e) --> 0.00076*9.869/(0.00025*0.03)

Evaluating ... ...

I = 1000.05866666667

STEP 3: Convert Result to Output's Unit

1000.05866666667 Ampere --> No Conversion Required

FINAL ANSWER

1000.05866666667 ≈ 1000.059 Ampere <-- Electric Current

(Calculation completed in 00.004 seconds)

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Created by Kumar Siddhant

Indian Institute of Information Technology, Design and Manufacturing (IIITDM), Jabalpur

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< 15 Current in ECM Calculators

Current Required in ECM

Go Electric Current = sqrt((Volume Flow Rate*Density of Electrolyte*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))/Resistance of Gap Between Work and Tool)

Current Efficiency given Gap between Tool and Work Surface

Go Current Efficiency in Decimal = Gap Between Tool and Work Surface*Specific Resistance of The Electrolyte*Work Piece Density*Feed Speed/(Supply Voltage*Electrochemical Equivalent)

Area of Work Exposed to Electrolysis given Tool Feed Speed

Go Area of Penetration = Electrochemical Equivalent*Current Efficiency in Decimal*Electric Current/(Feed Speed*Work Piece Density)

Electrochemical Equivalent of Work given Tool Feed Speed

Go Electrochemical Equivalent = Feed Speed*Work Piece Density*Area of Penetration/(Current Efficiency in Decimal*Electric Current)

Current Efficiency given Tool Feed Speed

Go Current Efficiency in Decimal = Feed Speed*Work Piece Density*Area of Penetration/(Electrochemical Equivalent*Electric Current)

Current Supplied given Tool Feed Speed

Go Electric Current = Feed Speed*Work Piece Density*Area of Penetration/(Electrochemical Equivalent*Current Efficiency in Decimal)

Tool Feed Speed given Current Supplied

Go Feed Speed = Current Efficiency in Decimal*Electrochemical Equivalent*Electric Current/(Work Piece Density*Area of Penetration)

Density of Work given Tool Feed Speed

Go Work Piece Density = Electrochemical Equivalent*Current Efficiency in Decimal*Electric Current/(Feed Speed*Area of Penetration)

Current Supplied for Electrolysis given Specific Resistivity of Electrolyte

Go Electric Current = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Specific Resistance of The Electrolyte)

Area of Work Exposed to Electrolysis given Supply Current

Go Area of Penetration = Specific Resistance of The Electrolyte*Gap Between Tool and Work Surface*Electric Current/Supply Voltage

Current Efficiency given Volumetric Material Removal Rate

Go Current Efficiency in Decimal = Metal Removal Rate*Work Piece Density/(Electrochemical Equivalent*Electric Current)

Current Supplied given Volumetric Material Removal Rate

Go Electric Current = Metal Removal Rate*Work Piece Density/(Electrochemical Equivalent*Current Efficiency in Decimal)

Resistance Owing to Electrolyte given Supply Current and Voltage

Go Ohmic Resistance = Supply Voltage/Electric Current

Current Supplied for Electrolysis

Go Electric Current = Supply Voltage/Ohmic Resistance

Supply Voltage for Electrolysis

Go Supply Voltage = Electric Current*Ohmic Resistance

Current Supplied for Electrolysis given Specific Resistivity of Electrolyte Formula

Electric Current = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Specific Resistance of The Electrolyte)
I = A*V_s/(h*r_e)

Reactions at Anode and Cathode

The possible reactions occurring at the cathode (at tool):
1. Evolution of hydrogen gas,
2. Neutralization of positively charged metal ions
At the anode also two possible reactions are occurring as follows:
1. Evolution of oxygen and halogen gas, and
2. Dissolution of metal ions.

How to Calculate Current Supplied for Electrolysis given Specific Resistivity of Electrolyte?

Current Supplied for Electrolysis given Specific Resistivity of Electrolyte calculator uses Electric Current = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Specific Resistance of The Electrolyte) to calculate the Electric Current, The Current Supplied for Electrolysis given Specific Resistivity of Electrolyte is a method to determine is the current that needs to be supplied for the ECM when the Specific Resistivity of the Electrolyte is known. Electric Current is denoted by I symbol.

How to calculate Current Supplied for Electrolysis given Specific Resistivity of Electrolyte using this online calculator? To use this online calculator for Current Supplied for Electrolysis given Specific Resistivity of Electrolyte, enter Area of Penetration (A), Supply Voltage (V_s), Gap Between Tool and Work Surface (h) & Specific Resistance of The Electrolyte (r_e) and hit the calculate button. Here is how the Current Supplied for Electrolysis given Specific Resistivity of Electrolyte calculation can be explained with given input values -> 1000.16 = 0.00076*9.869/(0.00025*0.03).

FAQ

What is Current Supplied for Electrolysis given Specific Resistivity of Electrolyte?

The Current Supplied for Electrolysis given Specific Resistivity of Electrolyte is a method to determine is the current that needs to be supplied for the ECM when the Specific Resistivity of the Electrolyte is known and is represented as I = A*V_s/(h*r_e) or Electric Current = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Specific Resistance of The Electrolyte). Area of Penetration is area of penetration of electrons, Supply Voltage is the voltage required to charge a given device within a given time, The Gap between Tool and Work Surface is the stretch of the distance between Tool and Work Surface during Electrochemical Machining & Specific Resistance of the electrolyte is the measure of how strongly it opposes the flow of current through them.

How to calculate Current Supplied for Electrolysis given Specific Resistivity of Electrolyte?

The Current Supplied for Electrolysis given Specific Resistivity of Electrolyte is a method to determine is the current that needs to be supplied for the ECM when the Specific Resistivity of the Electrolyte is known is calculated using Electric Current = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Specific Resistance of The Electrolyte). To calculate Current Supplied for Electrolysis given Specific Resistivity of Electrolyte, you need Area of Penetration (A), Supply Voltage (V_s), Gap Between Tool and Work Surface (h) & Specific Resistance of The Electrolyte (r_e). With our tool, you need to enter the respective value for Area of Penetration, Supply Voltage, Gap Between Tool and Work Surface & Specific Resistance of The Electrolyte and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

How many ways are there to calculate Electric Current?

In this formula, Electric Current uses Area of Penetration, Supply Voltage, Gap Between Tool and Work Surface & Specific Resistance of The Electrolyte. We can use 4 other way(s) to calculate the same, which is/are as follows -

Electric Current = Metal Removal Rate*Work Piece Density/(Electrochemical Equivalent*Current Efficiency in Decimal)
Electric Current = Feed Speed*Work Piece Density*Area of Penetration/(Electrochemical Equivalent*Current Efficiency in Decimal)
Electric Current = Supply Voltage/Ohmic Resistance
Electric Current = sqrt((Volume Flow Rate*Density of Electrolyte*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))/Resistance of Gap Between Work and Tool)

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