Workpiece surface speed given number of workpiece revolutions Calculator

✖The Number of Workpiece revolution is defined as the number of revolutions did workpiece take to complete the grinding.ⓘ Number of Workpiece revolution [m]			+10% -10%
✖Workpiece removal parameter is the ratio of the volume of workpiece removed per unit time per unit thrust force.ⓘ Workpiece removal parameter [Λ_W]			+10% -10%
✖Effective stiffness is the total extent to which a workpiece resists deformation in response to an applied force.ⓘ Effective stiffness [S_e]			+10% -10%
✖Width of grinding path is defined as the width of the path of the grinding tool.ⓘ Width of Grinding Path [a_p]			+10% -10%

✖Surface Speed of Workpiece is the speed of the surface rotating with respect to grinding tool.ⓘ Workpiece surface speed given number of workpiece revolutions [v_w]

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Formula

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Workpiece surface speed given number of workpiece revolutions

Formula

`"v"_{"w"} = "m"*"Λ"_{"W"}*"S"_{"e"}/(2*"a"_{"p"})`

Example

`"295454.5mm/s"="5"*"10"*"13N/m"/(2*"1100mm")`

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Workpiece surface speed given number of workpiece revolutions Solution

STEP 0: Pre-Calculation Summary

Formula Used

Surface Speed of Workpiece = Number of Workpiece revolution*Workpiece removal parameter*Effective stiffness/(2*Width of Grinding Path)
v_w = m*Λ_W*S_e/(2*a_p)
This formula uses 5 Variables

Variables Used

Surface Speed of Workpiece - (Measured in Meter per Second) - Surface Speed of Workpiece is the speed of the surface rotating with respect to grinding tool.
Number of Workpiece revolution - The Number of Workpiece revolution is defined as the number of revolutions did workpiece take to complete the grinding.
Workpiece removal parameter - Workpiece removal parameter is the ratio of the volume of workpiece removed per unit time per unit thrust force.
Effective stiffness - (Measured in Newton per Meter) - Effective stiffness is the total extent to which a workpiece resists deformation in response to an applied force.
Width of Grinding Path - (Measured in Meter) - Width of grinding path is defined as the width of the path of the grinding tool.

STEP 1: Convert Input(s) to Base Unit

Number of Workpiece revolution: 5 --> No Conversion Required
Workpiece removal parameter: 10 --> No Conversion Required
Effective stiffness: 13 Newton per Meter --> 13 Newton per Meter No Conversion Required
Width of Grinding Path: 1100 Millimeter --> 1.1 Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

v_w = m*Λ_W*S_e/(2*a_p) --> 5*10*13/(2*1.1)

Evaluating ... ...

v_w = 295.454545454545

STEP 3: Convert Result to Output's Unit

295.454545454545 Meter per Second -->295454.545454545 Millimeter per Second (Check conversion here)

FINAL ANSWER

295454.545454545 ≈ 295454.5 Millimeter per Second <-- Surface Speed of Workpiece

(Calculation completed in 00.004 seconds)

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National Institute of Technology (NIT), Srinagar

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National Institute Of Technology (NIT), Hamirpur

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< 14 Workpiece Calculators

Diameter of workpiece given feed and machine infeed speed

Go Diameter of Workpiece = Workpiece removal parameter*Diameter of Grinding Tool Wheel*((Machine Infeed speed/Feed Speed)-1)/Wheel Removal Parameter

Surface speed of workpiece given constant for grinding wheel

Go Surface Speed of Workpiece = (Maximum Undeformed Chip Thickness^2)*Surface Speed of Wheel/(Constant for particular grinding wheel*sqrt(Feed))

Workpiece diameter given equivalent wheel diameter

Go Diameter of Workpiece = Equivalent Wheel Diameter*Diameter of Grinding Tool Wheel/(Diameter of Grinding Tool Wheel-Equivalent Wheel Diameter)

Workpiece removal parameter given number of workpiece revolution

Go Workpiece removal parameter = 2*Surface Speed of Workpiece*Width of Grinding Path/(Number of Workpiece revolution*Effective stiffness)

Workpiece surface speed given number of workpiece revolutions

Go Surface Speed of Workpiece = Number of Workpiece revolution*Workpiece removal parameter*Effective stiffness/(2*Width of Grinding Path)

Width of Grinding path given number of workpiece revolutions

Go Width of Grinding Path = Number of Workpiece revolution*Workpiece removal parameter*Effective stiffness/(2*Surface Speed of Workpiece)

System stiffness given Number of workpiece revolution

Go Effective stiffness = 2*Surface Speed of Workpiece*Width of Grinding Path/(Workpiece removal parameter*Number of Workpiece revolution)

Number of workpiece revolution

Go Number of Workpiece revolution = 2*Surface Speed of Workpiece*Width of Grinding Path/(Workpiece removal parameter*Effective stiffness)

Diameter of workpiece given Metal removal rate

Go Diameter of Workpiece = Metal removal rate/(Feed Speed*pi*Width of Grinding Path)

Surface Speed of workpiece given Metal removal rate during grinding

Go Surface Speed of Workpiece = Material Removal Rate/(Feed*Width of Grinding Path)

Percentage Volume of Bond material in wheel of grinding

Go Percentage Volume of Bond Material in Grinding = (1.33*Wheel hardness number)+(2.2*Wheel structure number)-8

Number of workpiece revolutions given Time taken for spark out operation

Go Number of Workpiece revolution = Time taken for spark-out operation*Rotational Frequency

Rotational frequency of workpiece given Number of workpiece revolution

Go Rotational Frequency = Number of Workpiece revolution/Time taken for spark-out operation

Proportion of Total Energy flowing into workpiece

Go Proportion of total energy flowing into workpiece = (0.6+0.05*Relative Contact Area of Grain)*100

Workpiece surface speed given number of workpiece revolutions Formula

Surface Speed of Workpiece = Number of Workpiece revolution*Workpiece removal parameter*Effective stiffness/(2*Width of Grinding Path)
v_w = m*Λ_W*S_e/(2*a_p)

What is grinding used for?

Grinding is a machining process that's used to remove material from a workpiece via a grinding wheel. As the grinding wheel turns, it cuts material off the workpiece while creating a smooth surface texture in the process.

How to Calculate Workpiece surface speed given number of workpiece revolutions?

Workpiece surface speed given number of workpiece revolutions calculator uses Surface Speed of Workpiece = Number of Workpiece revolution*Workpiece removal parameter*Effective stiffness/(2*Width of Grinding Path) to calculate the Surface Speed of Workpiece, The Workpiece surface speed given number of workpiece revolutions is the speed of the surface rotating with respect to the grinding tool. Surface Speed of Workpiece is denoted by v_w symbol.

How to calculate Workpiece surface speed given number of workpiece revolutions using this online calculator? To use this online calculator for Workpiece surface speed given number of workpiece revolutions, enter Number of Workpiece revolution (m), Workpiece removal parameter (Λ_W), Effective stiffness (S_e) & Width of Grinding Path (a_p) and hit the calculate button. Here is how the Workpiece surface speed given number of workpiece revolutions calculation can be explained with given input values -> 3E+8 = 5*10*13/(2*1.1).

FAQ

What is Workpiece surface speed given number of workpiece revolutions?

The Workpiece surface speed given number of workpiece revolutions is the speed of the surface rotating with respect to the grinding tool and is represented as v_w = m*Λ_W*S_e/(2*a_p) or Surface Speed of Workpiece = Number of Workpiece revolution*Workpiece removal parameter*Effective stiffness/(2*Width of Grinding Path). The Number of Workpiece revolution is defined as the number of revolutions did workpiece take to complete the grinding, Workpiece removal parameter is the ratio of the volume of workpiece removed per unit time per unit thrust force, Effective stiffness is the total extent to which a workpiece resists deformation in response to an applied force & Width of grinding path is defined as the width of the path of the grinding tool.

How to calculate Workpiece surface speed given number of workpiece revolutions?

The Workpiece surface speed given number of workpiece revolutions is the speed of the surface rotating with respect to the grinding tool is calculated using Surface Speed of Workpiece = Number of Workpiece revolution*Workpiece removal parameter*Effective stiffness/(2*Width of Grinding Path). To calculate Workpiece surface speed given number of workpiece revolutions, you need Number of Workpiece revolution (m), Workpiece removal parameter (Λ_W), Effective stiffness (S_e) & Width of Grinding Path (a_p). With our tool, you need to enter the respective value for Number of Workpiece revolution, Workpiece removal parameter, Effective stiffness & Width of Grinding Path 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 Surface Speed of Workpiece?

In this formula, Surface Speed of Workpiece uses Number of Workpiece revolution, Workpiece removal parameter, Effective stiffness & Width of Grinding Path. We can use 2 other way(s) to calculate the same, which is/are as follows -

Surface Speed of Workpiece = Material Removal Rate/(Feed*Width of Grinding Path)
Surface Speed of Workpiece = (Maximum Undeformed Chip Thickness^2)*Surface Speed of Wheel/(Constant for particular grinding wheel*sqrt(Feed))

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