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Heat Required Per Unit Volume is the heat required for a certain purposes to be supplied per unit volume of material. Check FAQs
hv=αEPIßvA
hv - Heat Required Per Unit Volume?α - Heat Transfer Efficiency?EP - Electrode Potential?I - Electric Current?ß - Melting Efficiency?v - Travel Speed of Electrode?A - Area?

Net Heat Supplied to Joint Example

With values
With units
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Here is how the Net Heat Supplied to Joint equation looks like with Values.

Here is how the Net Heat Supplied to Joint equation looks like with Units.

Here is how the Net Heat Supplied to Joint equation looks like.

167.2405Edit=0.95Edit20.22Edit0.9577Edit0.4Edit5.5Edit50Edit
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Net Heat Supplied to Joint Solution

Follow our step by step solution on how to calculate Net Heat Supplied to Joint?

FIRST Step Consider the formula
hv=αEPIßvA
Next Step Substitute values of Variables
hv=0.9520.22V0.9577A0.45.5mm/s50
Next Step Convert Units
hv=0.9520.22V0.9577A0.40.0055m/s50
Next Step Prepare to Evaluate
hv=0.9520.220.95770.40.005550
Next Step Evaluate
hv=167.240539090909J/m³
LAST Step Rounding Answer
hv=167.2405J/m³

Net Heat Supplied to Joint Formula Elements

Variables
Heat Required Per Unit Volume
Heat Required Per Unit Volume is the heat required for a certain purposes to be supplied per unit volume of material.
Symbol: hv
Measurement: Energy DensityUnit: J/m³
Note: Value should be greater than 0.
Formulas to find Heat Required Per Unit VolumeOpen Variable
Heat Transfer Efficiency
Heat Transfer Efficiency is defined as the ratio of actual heat transfer to the theoretical heat transfer.
Symbol: α
Measurement: NAUnit: Unitless
Note: Value should be less than 1.
Formulas to find Heat Transfer EfficiencyOpen Variable
Electrode Potential
Electrode Potential is the electromotive force of a galvanic cell built from a standard reference electrode and another electrode to be characterized.
Symbol: EP
Measurement: Electric PotentialUnit: V
Note: Value should be greater than 0.
Formulas to find Electrode PotentialOpen Variable
Electric Current
Electric Current is the time rate of flow of charge through a cross sectional area.
Symbol: I
Measurement: Electric CurrentUnit: A
Note: Value should be greater than 0.
Formulas to find Electric CurrentOpen Variable
Melting Efficiency
Melting Efficiency is defined as the ratio of heat required to melt to the actual heat transfer.
Symbol: ß
Measurement: NAUnit: Unitless
Note: Value should be less than 1.
Formulas to find Melting EfficiencyOpen Variable
Travel Speed of Electrode
Travel Speed of Electrode is the speed at which an electrode travel during arc welding.
Symbol: v
Measurement: SpeedUnit: mm/s
Note: Value should be greater than 0.
Formulas to find Travel Speed of ElectrodeOpen Variable
Area
Area is the amount of two-dimensional space taken up by an object.
Symbol: A
Measurement: AreaUnit:
Note: Value should be greater than 0.
Formulas to find AreaOpen Variable

Other Formulas to find Heat Required Per Unit Volume

​Go Net Heat per Unit Volume available for Arc Welding
hv=PinvA

Other formulas in Heat Input in Welding category

​Go Total heat generated in resistance welding
H=kio2Rt
​Go Power given Electric Potential Difference and Electric Current
P=VI

How to Evaluate Net Heat Supplied to Joint?

Net Heat Supplied to Joint evaluator uses Heat Required Per Unit Volume = Heat Transfer Efficiency*Electrode Potential*Electric Current/(Melting Efficiency*Travel Speed of Electrode*Area) to evaluate the Heat Required Per Unit Volume, Net Heat Supplied to Joint can be defined as the total amount of heat energy transferred to the joint during a welding process, taking into account both the heat input from the welding arc or flame and any heat losses from the surroundings. Heat Required Per Unit Volume is denoted by hv symbol.

How to evaluate Net Heat Supplied to Joint using this online evaluator? To use this online evaluator for Net Heat Supplied to Joint, enter Heat Transfer Efficiency (α), Electrode Potential (EP), Electric Current (I), Melting Efficiency (ß), Travel Speed of Electrode (v) & Area (A) and hit the calculate button.

FAQs on Net Heat Supplied to Joint

What is the formula to find Net Heat Supplied to Joint?
The formula of Net Heat Supplied to Joint is expressed as Heat Required Per Unit Volume = Heat Transfer Efficiency*Electrode Potential*Electric Current/(Melting Efficiency*Travel Speed of Electrode*Area). Here is an example- 167.2405 = 0.95*20.22*0.9577/(0.4*0.0055*50).
How to calculate Net Heat Supplied to Joint?
With Heat Transfer Efficiency (α), Electrode Potential (EP), Electric Current (I), Melting Efficiency (ß), Travel Speed of Electrode (v) & Area (A) we can find Net Heat Supplied to Joint using the formula - Heat Required Per Unit Volume = Heat Transfer Efficiency*Electrode Potential*Electric Current/(Melting Efficiency*Travel Speed of Electrode*Area).
What are the other ways to Calculate Heat Required Per Unit Volume?
Here are the different ways to Calculate Heat Required Per Unit Volume-
  • Heat Required Per Unit Volume=Input Power/(Travel Speed of Electrode*Area)OpenImg
Can the Net Heat Supplied to Joint be negative?
No, the Net Heat Supplied to Joint, measured in Energy Density cannot be negative.
Which unit is used to measure Net Heat Supplied to Joint?
Net Heat Supplied to Joint is usually measured using the Joule per Cubic Meter[J/m³] for Energy Density. Kilojoule per Cubic Meter[J/m³], Megajoule per Cubic Meter[J/m³] are the few other units in which Net Heat Supplied to Joint can be measured.
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