Ambient Temperature during ECM Solution

STEP 0: Pre-Calculation Summary
Formula Used
Ambient Air Temperature = Boiling Point of Electrolyte-(Electric Current^2*Resistance of Gap Between Work And Tool)/(Density of Electrolyte*Specific Heat Capacity of Electrolyte*Maximum Volume Flow Rate)
θo = θB-(I^2*R)/(ρe*ce*Qmax)
This formula uses 7 Variables
Variables Used
Ambient Air Temperature - (Measured in Kelvin) - Ambient Air Temperature to the temperature of the air surrounding a particular object or area.
Boiling Point of Electrolyte - (Measured in Kelvin) - Boiling Point of Electrolyte is the temperature at which a liquid starts to boil and transforms to vapor.
Electric Current - (Measured in Ampere) - Electric current is the rate of flow of electric charge through a circuit, measured in amperes.
Resistance of Gap Between Work And Tool - (Measured in Ohm) - Resistance of Gap Between Work And Tool, often referred to as the "gap" in machining processes, depends on various factors such as the material being machined, the tool material and geometry.
Density of Electrolyte - (Measured in Kilogram per Cubic Meter) - The Density of Electrolyte shows the denseness of that electrolyte in a specific given area, this is taken as mass per unit volume of a given object.
Specific Heat Capacity of Electrolyte - (Measured in Joule per Kilogram per K) - Specific Heat Capacity of Electrolyte is the heat required to raise the temperature of the unit mass of a given substance by a given amount.
Maximum Volume Flow Rate - (Measured in Cubic Meter per Second) - Maximum Volume Flow Rate refers to the quantity of fluid (liquid or gas) that passes through a given surface per unit of time.
STEP 1: Convert Input(s) to Base Unit
Boiling Point of Electrolyte: 368.15 Kelvin --> 368.15 Kelvin No Conversion Required
Electric Current: 1000 Ampere --> 1000 Ampere No Conversion Required
Resistance of Gap Between Work And Tool: 0.012 Ohm --> 0.012 Ohm No Conversion Required
Density of Electrolyte: 997 Kilogram per Cubic Meter --> 997 Kilogram per Cubic Meter No Conversion Required
Specific Heat Capacity of Electrolyte: 4.18 Kilojoule per Kilogram per K --> 4180 Joule per Kilogram per K (Check conversion ​here)
Maximum Volume Flow Rate: 47991 Cubic Millimeter per Second --> 4.7991E-05 Cubic Meter per Second (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
θo = θB-(I^2*R)/(ρe*ce*Qmax) --> 368.15-(1000^2*0.012)/(997*4180*4.7991E-05)
Evaluating ... ...
θo = 308.150171857508
STEP 3: Convert Result to Output's Unit
308.150171857508 Kelvin --> No Conversion Required
FINAL ANSWER
308.150171857508 308.1502 Kelvin <-- Ambient Air Temperature
(Calculation completed in 00.020 seconds)

Credits

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Created by Rajat Vishwakarma
University Institute of Technology RGPV (UIT - RGPV), Bhopal
Rajat Vishwakarma has created this Calculator and 400+ more calculators!
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Verified by Parul Keshav
National Institute of Technology (NIT), Srinagar
Parul Keshav has verified this Calculator and 400+ more calculators!

Heat in Electrolyte Calculators

Flow Rate of Electrolyte from Heat Absorbed Electrolyte
​ LaTeX ​ Go Volume Flow Rate = Heat Absorption of Electrolyte/(Density of Electrolyte*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))
Density of Electrolyte from Heat Absorbed Electrolyte
​ LaTeX ​ Go Density of Electrolyte = Heat Absorption of Electrolyte/(Volume Flow Rate*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))
Specific Heat of Electrolyte
​ LaTeX ​ Go Specific Heat Capacity of Electrolyte = Heat Absorption of Electrolyte/(Volume Flow Rate*Density of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature))
Heat Absorbed by Electrolyte
​ LaTeX ​ Go Heat Absorption of Electrolyte = Volume Flow Rate*Density of Electrolyte*Specific Heat Capacity of Electrolyte*(Boiling Point of Electrolyte-Ambient Air Temperature)

Ambient Temperature during ECM Formula

​LaTeX ​Go
Ambient Air Temperature = Boiling Point of Electrolyte-(Electric Current^2*Resistance of Gap Between Work And Tool)/(Density of Electrolyte*Specific Heat Capacity of Electrolyte*Maximum Volume Flow Rate)
θo = θB-(I^2*R)/(ρe*ce*Qmax)

What is Faraday's I law of electrolysis ?

The first law of Faraday’s electrolysis states that the chemical change produced during electrolysis is proportional to the current passed and the electrochemical equivalence of the anode material.

How to Calculate Ambient Temperature during ECM?

Ambient Temperature during ECM calculator uses Ambient Air Temperature = Boiling Point of Electrolyte-(Electric Current^2*Resistance of Gap Between Work And Tool)/(Density of Electrolyte*Specific Heat Capacity of Electrolyte*Maximum Volume Flow Rate) to calculate the Ambient Air Temperature, The Ambient temperature during ECM formula is defined as the temperature of the surroundings where ECM is being done. This parameter helps in identifying heat dissipation. Ambient Air Temperature is denoted by θo symbol.

How to calculate Ambient Temperature during ECM using this online calculator? To use this online calculator for Ambient Temperature during ECM, enter Boiling Point of Electrolyte B), Electric Current (I), Resistance of Gap Between Work And Tool (R), Density of Electrolyte e), Specific Heat Capacity of Electrolyte (ce) & Maximum Volume Flow Rate (Qmax) and hit the calculate button. Here is how the Ambient Temperature during ECM calculation can be explained with given input values -> 21.2281 = 368.15-(1000^2*0.012)/(997*4180*4.7991E-05).

FAQ

What is Ambient Temperature during ECM?
The Ambient temperature during ECM formula is defined as the temperature of the surroundings where ECM is being done. This parameter helps in identifying heat dissipation and is represented as θo = θB-(I^2*R)/(ρe*ce*Qmax) or Ambient Air Temperature = Boiling Point of Electrolyte-(Electric Current^2*Resistance of Gap Between Work And Tool)/(Density of Electrolyte*Specific Heat Capacity of Electrolyte*Maximum Volume Flow Rate). Boiling Point of Electrolyte is the temperature at which a liquid starts to boil and transforms to vapor, Electric current is the rate of flow of electric charge through a circuit, measured in amperes, Resistance of Gap Between Work And Tool, often referred to as the "gap" in machining processes, depends on various factors such as the material being machined, the tool material and geometry, The Density of Electrolyte shows the denseness of that electrolyte in a specific given area, this is taken as mass per unit volume of a given object, Specific Heat Capacity of Electrolyte is the heat required to raise the temperature of the unit mass of a given substance by a given amount & Maximum Volume Flow Rate refers to the quantity of fluid (liquid or gas) that passes through a given surface per unit of time.
How to calculate Ambient Temperature during ECM?
The Ambient temperature during ECM formula is defined as the temperature of the surroundings where ECM is being done. This parameter helps in identifying heat dissipation is calculated using Ambient Air Temperature = Boiling Point of Electrolyte-(Electric Current^2*Resistance of Gap Between Work And Tool)/(Density of Electrolyte*Specific Heat Capacity of Electrolyte*Maximum Volume Flow Rate). To calculate Ambient Temperature during ECM, you need Boiling Point of Electrolyte B), Electric Current (I), Resistance of Gap Between Work And Tool (R), Density of Electrolyte e), Specific Heat Capacity of Electrolyte (ce) & Maximum Volume Flow Rate (Qmax). With our tool, you need to enter the respective value for Boiling Point of Electrolyte, Electric Current, Resistance of Gap Between Work And Tool, Density of Electrolyte, Specific Heat Capacity of Electrolyte & Maximum Volume Flow Rate 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 Ambient Air Temperature?
In this formula, Ambient Air Temperature uses Boiling Point of Electrolyte, Electric Current, Resistance of Gap Between Work And Tool, Density of Electrolyte, Specific Heat Capacity of Electrolyte & Maximum Volume Flow Rate. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Ambient Air Temperature = Boiling Point of Electrolyte-Heat Absorption of Electrolyte/(Maximum Volume Flow Rate*Density of Electrolyte*Specific Heat Capacity of Electrolyte)
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