Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining Calculator

✖Cutting Force is the force in the direction of cutting, the same direction as the cutting speed.ⓘ Cutting Force [F_c]			+10% -10%
✖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.ⓘ Specific Cutting Energy in Machining [p_s]			+10% -10%

✖The Cross-sectional Area of Uncut Chip is the area enclosed within the outer surface of the workpiece and the line of cut followed by the single-point cutting edge. It is calculated for one pass.ⓘ Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining [A_c]

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Formula

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Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining

Formula

`"A"_{"c"} = "F"_{"c"}/"p"_{"s"}`

Example

`"0.4505mm²"="901N"/"2000MJ/m³"`

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Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining Solution

STEP 0: Pre-Calculation Summary

Formula Used

Cross-sectional Area of Uncut Chip = Cutting Force/Specific Cutting Energy in Machining
A_c = F_c/p_s
This formula uses 3 Variables

Variables Used

Cross-sectional Area of Uncut Chip - (Measured in Square Meter) - The Cross-sectional Area of Uncut Chip is the area enclosed within the outer surface of the workpiece and the line of cut followed by the single-point cutting edge. It is calculated for one pass.
Cutting Force - (Measured in Newton) - Cutting Force is the force in the direction of cutting, the same direction as the cutting speed.
Specific Cutting Energy in Machining - (Measured in Joule per Cubic Meter) - 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.

STEP 1: Convert Input(s) to Base Unit

Cutting Force: 901 Newton --> 901 Newton No Conversion Required
Specific Cutting Energy in Machining: 2000 Megajoule per Cubic Meter --> 2000000000 Joule per Cubic Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

A_c = F_c/p_s --> 901/2000000000

Evaluating ... ...

A_c = 4.505E-07

STEP 3: Convert Result to Output's Unit

4.505E-07 Square Meter -->0.4505 Square Millimeter (Check conversion here)

FINAL ANSWER

0.4505 Square Millimeter <-- Cross-sectional Area of Uncut Chip

(Calculation completed in 00.004 seconds)

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Credits

Created by Parul Keshav

National Institute of Technology (NIT), Srinagar

Parul Keshav has created this Calculator and 300+ more calculators!

Verified by Kethavath Srinath

Osmania University (OU), Hyderabad

Kethavath Srinath has verified this Calculator and 1200+ more calculators!

< 25 Chip Control Calculators

Chip breaker height given Chip breaker wedge angle

Go Chip Breaker Height = ((Chip-Breaker Distance-Length of Chip Tool Contact)-(Radius of Chip Curvature/cot(Chip Breaker Wedge Angle/(2))))/cot(Chip Breaker Wedge Angle)

Radius of Chip given Chip breaker wedge angle

Go Radius of Chip Curvature = ((Chip-Breaker Distance-Length of Chip Tool Contact)-(Chip Breaker Height*cot(Chip Breaker Wedge Angle)))*cot(Chip Breaker Wedge Angle/(2))

Length of chip tool contact given Chip breaker wedge angle

Go Length of Chip Tool Contact = Chip-Breaker Distance-(Radius of Chip Curvature/cot(Chip Breaker Wedge Angle/(2)))-(Chip Breaker Height*cot(Chip Breaker Wedge Angle))

Chip breaker distance given Chip breaker wedge angle

Go Chip-Breaker Distance = Radius of Chip Curvature/cot(Chip Breaker Wedge Angle/(2))+(Chip Breaker Height*cot(Chip Breaker Wedge Angle))+Length of Chip Tool Contact

Length of chip tool contact given radius of chip curvature

Go Length of Chip Tool Contact = Chip-Breaker Distance-sqrt((Radius of Chip Curvature*2*Chip Breaker Height)-(Chip Breaker Height^2))

Chip breaker distance given radius of chip curvature

Go Chip-Breaker Distance = sqrt((Radius of Chip Curvature*2*Chip Breaker Height)-(Chip Breaker Height^2))+Length of Chip Tool Contact

Chip break distance when material constant is unity

Go Chip-Breaker Distance = sqrt((Radius of Chip Curvature*2*Chip Breaker Height)-(Chip Breaker Height^2))+Chip Thickness

Chip Thickness when material constant is unity

Go Chip Thickness = Chip-Breaker Distance-sqrt((Radius of Chip Curvature*2*Chip Breaker Height)-(Chip Breaker Height^2))

Radius of Chip curvature

Go Radius of Chip Curvature = ((Chip-Breaker Distance-Length of Chip Tool Contact)^2)/(2*Chip Breaker Height)+(Chip Breaker Height/2)

Radius of Chip curvature when material constant is unity

Go Radius of Chip Curvature = ((Chip-Breaker Distance-Chip Thickness)^2)/(2*Chip Breaker Height)+(Chip Breaker Height/2)

Density of Workpiece given Thickness of Chip

Go Density of work piece = Mass of Chip/(Chip Thickness*Length of Chip*Width of Chip)

Length of Chip using Thickness of Chip

Go Length of Chip = Mass of Chip/(Chip Thickness*Width of Chip*Density of work piece)

Width of Chip given Thickness of Chip

Go Width of Chip = Mass of Chip/(Length of Chip*Chip Thickness*Density of work piece)

Chip Thickness

Go Chip Thickness = Mass of Chip/(Length of Chip*Width of Chip*Density of work piece)

Mass of Chip given Thickness of Chip

Go Mass of Chip = Chip Thickness*Length of Chip*Width of Chip*Density of work piece

Metal Removal Rate given Specific Cutting Energy

Go Metal removal rate = Rate of Energy Consumption during Machining/Specific Cutting Energy in Machining

Undeformed Chip Thickness using Length of Shear Plane of Chip

Go Undeformed Chip Thickness = Length of Shear Plane*sin(Shear angle)

Length of Shear Plane of Chip

Go Length of Shear Plane = Undeformed Chip Thickness/sin(Shear angle)

Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining

Go Cross-sectional Area of Uncut Chip = Cutting Force/Specific Cutting Energy in Machining

Chip thickness given length of chip tool contact

Go Chip Thickness = Length of Chip Tool Contact/Material Constant

Undeformed Chip Thickness using Cutting Ratio

Go Undeformed Chip Thickness = Cutting Ratio*Uncut Chip Thickness

Constant for length of chip tool contact

Go Material Constant = Length of Chip Tool Contact/Chip Thickness

Chip Thickness given Cutting Ratio

Go Uncut Chip Thickness = Undeformed Chip Thickness/Cutting Ratio

Length of chip tool contact

Go Length of Chip Tool Contact = Chip Thickness*Material Constant

Cutting Ratio

Go Cutting Ratio = Undeformed Chip Thickness/Uncut Chip Thickness

Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining Formula

Cross-sectional Area of Uncut Chip = Cutting Force/Specific Cutting Energy in Machining
A_c = F_c/p_s

What is uncut chip thickness?

Uncut chip thickness is comparable to cutting edge radius in micromachining. If the uncut chip thickness is less than a critical value, there will be no chip formation. This critical value is termed as minimum uncut chip thickness (MUCT).

How to Calculate Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining?

Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining calculator uses Cross-sectional Area of Uncut Chip = Cutting Force/Specific Cutting Energy in Machining to calculate the Cross-sectional Area of Uncut Chip, Cross Sectional area of Uncut chip using Specific Cutting energy in machining is defined as the front area of cross-section of the chip from where it is going to cut. Cross-sectional Area of Uncut Chip is denoted by A_c symbol.

How to calculate Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining using this online calculator? To use this online calculator for Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining, enter Cutting Force (F_c) & Specific Cutting Energy in Machining (p_s) and hit the calculate button. Here is how the Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining calculation can be explained with given input values -> 450500 = 901/2000000000.

FAQ

What is Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining?

Cross Sectional area of Uncut chip using Specific Cutting energy in machining is defined as the front area of cross-section of the chip from where it is going to cut and is represented as A_c = F_c/p_s or Cross-sectional Area of Uncut Chip = Cutting Force/Specific Cutting Energy in Machining. Cutting Force is the force in the direction of cutting, the same direction as the cutting speed & 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.

How to calculate Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining?

Cross Sectional area of Uncut chip using Specific Cutting energy in machining is defined as the front area of cross-section of the chip from where it is going to cut is calculated using Cross-sectional Area of Uncut Chip = Cutting Force/Specific Cutting Energy in Machining. To calculate Cross Sectional Area of Uncut chip using Specific Cutting energy in Machining, you need Cutting Force (F_c) & Specific Cutting Energy in Machining (p_s). With our tool, you need to enter the respective value for Cutting Force & Specific Cutting Energy in Machining and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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