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Specific cutting energy given Initial weight of workpiece Formula

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Specific Cutting Energy in Machining is the energy consumed to remove a unit volume of material, which is calculated as the ratio of cutting energy e to material removal volume v. Check FAQs

p s = \frac{t p \cdot ρ \cdot a}{V 0 \cdot W^{1 - b}}

p_s - Specific Cutting Energy in Machining?t_p - Machining Time For Maximum Power?ρ - Density of Work Piece?a - Constant For Tool Type(a)?V₀ - Proportion of Initial Volume?W - Initial Work Piece Weight?b - Constant For Tool Type(b)?

Specific cutting energy given Initial weight of workpiece Example

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Here is how the Specific cutting energy given Initial weight of workpiece equation looks like with Values.

Here is how the Specific cutting energy given Initial weight of workpiece equation looks like with Units.

Here is how the Specific cutting energy given Initial weight of workpiece equation looks like.

3000.487 = \frac{48.925 \cdot 7850 \cdot 2.9}{0.0001 \cdot {12.8}^{1 - 0.53}}

3000.487MJ/m³ = \frac{48.925s \cdot 7850kg/m³ \cdot 2.9}{0.0001 \cdot {12.8kg}^{1 - 0.53}}

3000.487 = \frac{48.925 \cdot 7850 \cdot 2.9}{0.0001 \cdot {12.8}^{1 - 0.53}}

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Specific cutting energy given Initial weight of workpiece Solution

Follow our step by step solution on how to calculate Specific cutting energy given Initial weight of workpiece?

FIRST Step Consider the formula

p s = \frac{t p \cdot ρ \cdot a}{V 0 \cdot W^{1 - b}}

Next Step Substitute values of Variables

∴

p s = \frac{48.925s \cdot 7850kg/m³ \cdot 2.9}{0.0001 \cdot {12.8kg}^{1 - 0.53}}

Next Step Prepare to Evaluate

∴

p s = \frac{48.925 \cdot 7850 \cdot 2.9}{0.0001 \cdot {12.8}^{1 - 0.53}}

Next Step Evaluate

∴

p s = 3000487000J/m³

LAST Step Convert to Output's Unit

∴

p s = 3000.487MJ/m³

Specific cutting energy given Initial weight of workpiece Formula Elements

Variables

Specific Cutting Energy in Machining

Specific Cutting Energy in Machining is the energy consumed to remove a unit volume of material, which is calculated as the ratio of cutting energy e to material removal volume v.

Symbol: p_s

Measurement: Energy DensityUnit: MJ/m³

Note: Value should be greater than 0.

Formulas to find Specific Cutting Energy in Machining

Machining Time For Maximum Power

Machining Time For Maximum Power is the time for processing when the workpiece is machined under maximum power conditions.

Symbol: t_p

Measurement: TimeUnit: s

Note: Value should be greater than 0.

Formulas to find Machining Time For Maximum Power

Density of Work Piece

The Density of Work Piece is the mass per unit volume ratio of the material of workpiece.

Symbol: ρ

Measurement: DensityUnit: kg/m³

Note: Value should be greater than 0.

Formulas to find Density of Work Piece

Constant For Tool Type(a)

Constant For Tool Type(a) is defined as the constant for the type of material used in the tool.

Symbol: a

Measurement: NAUnit: Unitless

Note: Value can be positive or negative.

Formulas to find Constant For Tool Type(a)

Proportion of Initial Volume

The Proportion of Initial Volume or weight is the proportion of initial volume or initial weight to be removed by machining.

Symbol: V₀

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Proportion of Initial Volume

Initial Work Piece Weight

Initial Work Piece Weight is defined as the weight of the work piece before undergoing machining operation.

Symbol: W

Measurement: WeightUnit: kg

Note: Value should be greater than 0.

Formulas to find Initial Work Piece Weight

Constant For Tool Type(b)

Constant For Tool Type(b) is defined as the constant for the type of material used in the tool.

Symbol: b

Measurement: NAUnit: Unitless

Note: Value can be positive or negative.

Formulas to find Constant For Tool Type(b)

Other formulas in Initial Weight of Workpiece category

Go Surface area of Workpiece given Surface Generation rate

A m = (t s \cdot R sg)

Go Length of Workpiece given Machining time for maximum power

L = \frac{t p \cdot P m}{p s \cdot π \cdot d w \cdot d cut}

How to Evaluate Specific cutting energy given Initial weight of workpiece?

Specific cutting energy given Initial weight of workpiece evaluator uses Specific Cutting Energy in Machining = (Machining Time For Maximum Power*Density of Work Piece*Constant For Tool Type(a))/(Proportion of Initial Volume*Initial Work Piece Weight^(1-Constant For Tool Type(b))) to evaluate the Specific Cutting Energy in Machining, The Specific cutting energy given Initial weight of workpiece is the energy consumed to remove a unit volume of material, which is calculated as the ratio of cutting energy E to material removal volume V. Specific Cutting Energy in Machining is denoted by p_s symbol.

How to evaluate Specific cutting energy given Initial weight of workpiece using this online evaluator? To use this online evaluator for Specific cutting energy given Initial weight of workpiece, enter Machining Time For Maximum Power (t_p), Density of Work Piece (ρ), Constant For Tool Type(a) (a), Proportion of Initial Volume (V₀), Initial Work Piece Weight (W) & Constant For Tool Type(b) (b) and hit the calculate button.

FAQs on Specific cutting energy given Initial weight of workpiece

What is the formula to find Specific cutting energy given Initial weight of workpiece?

The formula of Specific cutting energy given Initial weight of workpiece is expressed as Specific Cutting Energy in Machining = (Machining Time For Maximum Power*Density of Work Piece*Constant For Tool Type(a))/(Proportion of Initial Volume*Initial Work Piece Weight^(1-Constant For Tool Type(b))). Here is an example- 0.003 = (48.925*7850*2.9)/(0.000112*12.79999^(1-0.529999827884223)).

How to calculate Specific cutting energy given Initial weight of workpiece?

With Machining Time For Maximum Power (t_p), Density of Work Piece (ρ), Constant For Tool Type(a) (a), Proportion of Initial Volume (V₀), Initial Work Piece Weight (W) & Constant For Tool Type(b) (b) we can find Specific cutting energy given Initial weight of workpiece using the formula - Specific Cutting Energy in Machining = (Machining Time For Maximum Power*Density of Work Piece*Constant For Tool Type(a))/(Proportion of Initial Volume*Initial Work Piece Weight^(1-Constant For Tool Type(b))).

Can the Specific cutting energy given Initial weight of workpiece be negative?

No, the Specific cutting energy given Initial weight of workpiece, measured in Energy Density cannot be negative.

Which unit is used to measure Specific cutting energy given Initial weight of workpiece?

Specific cutting energy given Initial weight of workpiece is usually measured using the Megajoule per Cubic Meter[MJ/m³] for Energy Density. Joule per Cubic Meter[MJ/m³], Kilojoule per Cubic Meter[MJ/m³] are the few other units in which Specific cutting energy given Initial weight of workpiece can be measured.

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Specific cutting energy given Initial weight of workpiece Formula

Specific cutting energy given Initial weight of workpiece Example

Specific cutting energy given Initial weight of workpiece Solution

Specific cutting energy given Initial weight of workpiece Formula Elements

Other formulas in Initial Weight of Workpiece category

How to Evaluate Specific cutting energy given Initial weight of workpiece?

FAQs on Specific cutting energy given Initial weight of workpiece

Variable Name