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Vaporisation Energy of Material Formula

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Vaporisation Energy of Material is the energy required to turn the material into vapor. Check FAQs

E = \frac{A 0 \cdot P out}{V c \cdot A beam \cdot t}

E - Vaporisation Energy of Material?A₀ - Empirical Constant?P_out - Laser Energy during Cut Rate?V_c - Cutting Rate?A_beam - Laser Beam Area at Focal Point?t - Thickness?

Vaporisation Energy of Material Example

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With units

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Here is how the Vaporisation Energy of Material equation looks like with Values.

Here is how the Vaporisation Energy of Material equation looks like with Units.

Here is how the Vaporisation Energy of Material equation looks like.

10 = \frac{0.408 \cdot 10.397}{10.1 \cdot 2.1 \cdot 1.2}

10W/mm³ = \frac{0.408 \cdot 10.397W}{10.1mm/min \cdot 2.1mm² \cdot 1.2m}

10 = \frac{0.408 \cdot 10.397}{10.1 \cdot 2.1 \cdot 1.2}

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Vaporisation Energy of Material Solution

Follow our step by step solution on how to calculate Vaporisation Energy of Material?

FIRST Step Consider the formula

E = \frac{A 0 \cdot P out}{V c \cdot A beam \cdot t}

Next Step Substitute values of Variables

∴

E = \frac{0.408 \cdot 10.397W}{10.1mm/min \cdot 2.1mm² \cdot 1.2m}

Next Step Convert Units

∴

E = \frac{0.408 \cdot 10.397W}{0.0002m/s \cdot 2.1E-6m² \cdot 1.2m}

Next Step Prepare to Evaluate

∴

E = \frac{0.408 \cdot 10.397}{0.0002 \cdot 2.1E-6 \cdot 1.2}

Next Step Evaluate

∴

E = 9999956518.09093W/m³

Next Step Convert to Output's Unit

∴

E = 9.99995651809093W/mm³

LAST Step Rounding Answer

∴

E = 10W/mm³

Vaporisation Energy of Material Formula Elements

Variables

Vaporisation Energy of Material

Vaporisation Energy of Material is the energy required to turn the material into vapor.

Symbol: E

Measurement: Power DensityUnit: W/mm³

Note: Value should be greater than 0.

Formulas to find Vaporisation Energy of Material

Empirical Constant

The Empirical Constant is a self-determined constant whose value is accessible from table of such constants. This constant is used to calculate the intrinsic carrier concentration.

Symbol: A₀

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Empirical Constant

Laser Energy during Cut Rate

Laser Energy during Cut Rate is the energy released from the laser used in LBM.

Symbol: P_out

Measurement: PowerUnit: W

Note: Value should be greater than 0.

Formulas to find Laser Energy during Cut Rate

Cutting Rate

Cutting Rate is the rate at which cutting takes place in length per time.

Symbol: V_c

Measurement: SpeedUnit: mm/min

Note: Value should be greater than 0.

Formulas to find Cutting Rate

Laser Beam Area at Focal Point

Laser Beam Area at Focal Point refers to the cross-sectional area of a laser beam at the focal point of a focusing lens or mirror.

Symbol: A_beam

Measurement: AreaUnit: mm²

Note: Value should be greater than 0.

Formulas to find Laser Beam Area at Focal Point

Thickness

Thickness refers to the measurement of the distance through an object or material from one surface to its opposite surface. It indicates how thick the object or material is.

Symbol: t

Measurement: LengthUnit: m

Note: Value should be greater than 0.

Formulas to find Thickness

Other formulas in Cutting Rate in LBM category

Go Cutting Rate

V c = \frac{A 0 \cdot P out}{E \cdot A beam \cdot t}

Go Constant Dependent of Material

A 0 = V c \cdot \frac{E \cdot A beam \cdot t}{P out}

Go Laser Power Incident on Surface

P out = V c \cdot \frac{E \cdot A beam \cdot t}{A 0}

Go Area of Laser Beam at Focal Point

A beam = \frac{A 0 \cdot P out}{E \cdot V c \cdot t}

How to Evaluate Vaporisation Energy of Material?

Vaporisation Energy of Material evaluator uses Vaporisation Energy of Material = (Empirical Constant*Laser Energy during Cut Rate)/(Cutting Rate*Laser Beam Area at Focal Point*Thickness) to evaluate the Vaporisation Energy of Material, The Vaporisation Energy of Material formula is defined as energy required per unit volume of material to convert it to vapor state. Vaporisation Energy of Material is denoted by E symbol.

How to evaluate Vaporisation Energy of Material using this online evaluator? To use this online evaluator for Vaporisation Energy of Material, enter Empirical Constant (A₀), Laser Energy during Cut Rate (P_out), Cutting Rate (V_c), Laser Beam Area at Focal Point (A_beam) & Thickness (t) and hit the calculate button.

FAQs on Vaporisation Energy of Material

What is the formula to find Vaporisation Energy of Material?

The formula of Vaporisation Energy of Material is expressed as Vaporisation Energy of Material = (Empirical Constant*Laser Energy during Cut Rate)/(Cutting Rate*Laser Beam Area at Focal Point*Thickness). Here is an example- 1E-8 = (0.408*10.397)/(0.000168333333333333*2.099999E-06*1.199999).

How to calculate Vaporisation Energy of Material?

With Empirical Constant (A₀), Laser Energy during Cut Rate (P_out), Cutting Rate (V_c), Laser Beam Area at Focal Point (A_beam) & Thickness (t) we can find Vaporisation Energy of Material using the formula - Vaporisation Energy of Material = (Empirical Constant*Laser Energy during Cut Rate)/(Cutting Rate*Laser Beam Area at Focal Point*Thickness).

Can the Vaporisation Energy of Material be negative?

No, the Vaporisation Energy of Material, measured in Power Density cannot be negative.

Which unit is used to measure Vaporisation Energy of Material?

Vaporisation Energy of Material is usually measured using the Watt Per Cubic Millimeter[W/mm³] for Power Density. Horsepower Per Litre[W/mm³], Decawatt Per Cubic Meter[W/mm³], Gigawatt Per Cubic Meter[W/mm³] are the few other units in which Vaporisation Energy of Material can be measured.

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Vaporisation Energy of Material Formula

Vaporisation Energy of Material Example

Vaporisation Energy of Material Solution

Vaporisation Energy of Material Formula Elements

Other formulas in Cutting Rate in LBM category

How to Evaluate Vaporisation Energy of Material?

FAQs on Vaporisation Energy of Material

Variable Name