Specific Resistivity of Electrolyte given Supply Current 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%
✖Electric current is the rate of flow of electric charge through a circuit, measured in amperes.ⓘ Electric Current [I]			+10% -10%

✖Specific Resistance of the electrolyte is the measure of how strongly it opposes the flow of current through them.ⓘ Specific Resistivity of Electrolyte given Supply Current [r_e]

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Formula

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Specific Resistivity of Electrolyte given Supply Current

Formula

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

Example

`"3.000176Ω*cm"="7.6cm²"*"9.869V"/("0.25mm"*"1000A")`

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Specific Resistivity of Electrolyte given Supply Current Solution

STEP 0: Pre-Calculation Summary

Formula Used

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

Variables Used

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.
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.
Electric Current - (Measured in Ampere) - Electric current is the rate of flow of electric charge through a circuit, measured in amperes.

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)
Electric Current: 1000 Ampere --> 1000 Ampere No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

r_e = A*V_s/(h*I) --> 0.00076*9.869/(0.00025*1000)

Evaluating ... ...

r_e = 0.03000176

STEP 3: Convert Result to Output's Unit

0.03000176 Ohm Meter -->3.000176 Ohm Centimeter (Check conversion here)

FINAL ANSWER

3.000176 Ohm Centimeter <-- Specific Resistance of The Electrolyte

(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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National Institute of Technology (NIT), Srinagar

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< 14 Gap Resistance Calculators

Flow Rate of Electrolytes from Gap Resistance ECM

Go Volume Flow Rate = (Electric Current^2*Resistance of Gap Between Work and Tool)/(Density of Electrolyte*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))

Density of Electrolyte

Go Density of Electrolyte = (Electric Current^2*Resistance of Gap Between Work and Tool)/(Volume Flow Rate*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))

Gap Resistance from Electrolyte Flow Rate

Go Resistance of Gap Between Work and Tool = (Volume Flow Rate*Density of Electrolyte*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))/Electric Current^2

Specific Resistivity of Electrolyte given Gap between Tool and Work Surface

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

Density of Work Material given Gap between Tool and Work Surface

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

Tool Feed Speed given Gap between Tool and Work Surface

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

Supply Voltage given Gap between Tool and Work Surface

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

Gap between Tool and Work Surface

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

Specific Resistivity of Electrolyte given Supply Current

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

Gap between Tool and Work Surface given Supply Current

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

Gap Resistance between Work and Tool

Go Resistance of Gap Between Work and Tool = (Specific Resistance of The Electrolyte*Gap Between Tool and Work Surface)/Cross Sectional Area of Gap

Specific Resistance of Electrolyte

Go Specific Resistance of The Electrolyte = (Resistance of Gap Between Work and Tool*Cross Sectional Area of Gap)/Gap Between Tool and Work Surface

Cross-Sectional Area of Gap

Go Cross Sectional Area of Gap = (Specific Resistance of The Electrolyte*Gap Between Tool and Work Surface)/Resistance of Gap Between Work and Tool

Width of Equilibrium Gap

Go Gap Between Tool and Work Surface = (Resistance of Gap Between Work and Tool*Cross Sectional Area of Gap)/Specific Resistance of The Electrolyte

Specific Resistivity of Electrolyte given Supply Current Formula

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

Factors related to Electrolyte in ECM

1. Temperature and pressure - The difference in the temperature of the electrolyte at the
entrance and exit of the tool work gap is an important factor.
2. Concentration - A concentrated electrolyte offers low resistance to the flow of machining
current. Dilute electrolytes are used when the surface finish is most important.
3. Electrolyte flow - The electrolyte is pumped from a storage tank via a pressure controller
and a filter to the machining gap.

How to Calculate Specific Resistivity of Electrolyte given Supply Current?

Specific Resistivity of Electrolyte given Supply Current calculator uses Specific Resistance of The Electrolyte = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Electric Current) to calculate the Specific Resistance of The Electrolyte, The Specific Resistivity of Electrolyte given Supply Current is a method to determine the required Specific Resistivity of the Electrolyte to be used for a required Volumetric Flow Rate when the Current Supplied is fixed. Specific Resistance of The Electrolyte is denoted by r_e symbol.

How to calculate Specific Resistivity of Electrolyte given Supply Current using this online calculator? To use this online calculator for Specific Resistivity of Electrolyte given Supply Current, enter Area of Penetration (A), Supply Voltage (V_s), Gap Between Tool and Work Surface (h) & Electric Current (I) and hit the calculate button. Here is how the Specific Resistivity of Electrolyte given Supply Current calculation can be explained with given input values -> 300.048 = 0.00076*9.869/(0.00025*1000).

FAQ

What is Specific Resistivity of Electrolyte given Supply Current?

The Specific Resistivity of Electrolyte given Supply Current is a method to determine the required Specific Resistivity of the Electrolyte to be used for a required Volumetric Flow Rate when the Current Supplied is fixed and is represented as r_e = A*V_s/(h*I) or Specific Resistance of The Electrolyte = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Electric Current). 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 & Electric current is the rate of flow of electric charge through a circuit, measured in amperes.

How to calculate Specific Resistivity of Electrolyte given Supply Current?

The Specific Resistivity of Electrolyte given Supply Current is a method to determine the required Specific Resistivity of the Electrolyte to be used for a required Volumetric Flow Rate when the Current Supplied is fixed is calculated using Specific Resistance of The Electrolyte = Area of Penetration*Supply Voltage/(Gap Between Tool and Work Surface*Electric Current). To calculate Specific Resistivity of Electrolyte given Supply Current, you need Area of Penetration (A), Supply Voltage (V_s), Gap Between Tool and Work Surface (h) & Electric Current (I). With our tool, you need to enter the respective value for Area of Penetration, Supply Voltage, Gap Between Tool and Work Surface & Electric Current 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 Specific Resistance of The Electrolyte?

In this formula, Specific Resistance of The Electrolyte uses Area of Penetration, Supply Voltage, Gap Between Tool and Work Surface & Electric Current. We can use 2 other way(s) to calculate the same, which is/are as follows -

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

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