Diameter of workpiece given Constant for Cylindrical Turning Calculator

✖Constant For Machining Condition can be regarded as the distance moved by the tool corner relative to the workpiece during a particular machining condition. It is usually measured in "Metre".ⓘ Constant For Machining Condition [K]			+10% -10%
✖The Feed is the distance the cutting tool advances along the length of the work for every revolution of the spindle.ⓘ Feed [f_in]			+10% -10%
✖Length of cut (LOC) is a measurement of the functional cutting depth in the axial direction for a machining process.ⓘ Length of Cut [L_cut]			+10% -10%

✖The Diameter of Workpiece is defined as the diameter of the workpiece which is undergoing grinding.ⓘ Diameter of workpiece given Constant for Cylindrical Turning [d_workpiece]

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Formula

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Diameter of workpiece given Constant for Cylindrical Turning

Formula

`"d"_{"workpiece"} = "K"*"f"_{"in"}/(pi*"L"_{"cut"})`

Example

`"38.1975mm"="1200.01mm"*"0.9mm"/(pi*"9mm")`

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Diameter of workpiece given Constant for Cylindrical Turning Solution

STEP 0: Pre-Calculation Summary

Formula Used

Diameter of Workpiece = Constant For Machining Condition*Feed/(pi*Length of Cut)
d_workpiece = K*f_in/(pi*L_cut)
This formula uses 1 Constants, 4 Variables

Constants Used

pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288

Variables Used

Diameter of Workpiece - (Measured in Meter) - The Diameter of Workpiece is defined as the diameter of the workpiece which is undergoing grinding.
Constant For Machining Condition - (Measured in Meter) - Constant For Machining Condition can be regarded as the distance moved by the tool corner relative to the workpiece during a particular machining condition. It is usually measured in "Metre".
Feed - (Measured in Meter) - The Feed is the distance the cutting tool advances along the length of the work for every revolution of the spindle.
Length of Cut - (Measured in Meter) - Length of cut (LOC) is a measurement of the functional cutting depth in the axial direction for a machining process.

STEP 1: Convert Input(s) to Base Unit

Constant For Machining Condition: 1200.01 Millimeter --> 1.20001 Meter (Check conversion here)
Feed: 0.9 Millimeter --> 0.0009 Meter (Check conversion here)
Length of Cut: 9 Millimeter --> 0.009 Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

d_workpiece = K*f_in/(pi*L_cut) --> 1.20001*0.0009/(pi*0.009)

Evaluating ... ...

d_workpiece = 0.0381975046519411

STEP 3: Convert Result to Output's Unit

0.0381975046519411 Meter -->38.1975046519411 Millimeter (Check conversion here)

FINAL ANSWER

38.1975046519411 ≈ 38.1975 Millimeter <-- Diameter of Workpiece

(Calculation completed in 00.004 seconds)

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Created by Kumar Siddhant

Indian Institute of Information Technology, Design and Manufacturing (IIITDM), Jabalpur

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< 17 Turning Operation Calculators

Batch size given Non-productive time in turning

Go Batch Size = (Basic Setup Time+Number of Tools Used*Setup Time per Tool)/((Non-Productive Time-Loading and Unloading Time-(Tool Positioning Time per Operation*Number of Operations)))

Tool positioning time per operation given Non-productive time in turning

Go Tool Positioning Time per Operation = (Non-Productive Time-((Basic Setup Time+Number of Tools Used*Setup Time per Tool)/Batch Size)-Loading and Unloading Time)/Number of Operations

Loading and unloading time given Non-productive time in turning

Go Loading and Unloading Time = Non-Productive Time-((Basic Setup Time+Number of Tools Used*Setup Time per Tool)/Batch Size)-(Tool Positioning Time per Operation*Number of Operations)

Set-up Time per tool terms of Non-productive time in turning

Go Setup Time per Tool = ((Non-Productive Time-Loading and Unloading Time-(Tool Positioning Time per Operation*Number of Operations))*Batch Size-Basic Setup Time)/Number of Tools Used

Number of operations given Non-productive time in turning

Go Number of Operations = (Non-Productive Time-((Basic Setup Time+Number of Tools Used*Setup Time per Tool)/Batch Size)-Loading and Unloading Time)/Tool Positioning Time per Operation

Basic setup time given Non-productive time in turning

Go Basic Setup Time = (Non-Productive Time-Loading and Unloading Time-(Tool Positioning Time per Operation*Number of Operations))*Batch Size-(Number of Tools Used*Setup Time per Tool)

Number of tools given Non-productive time in turning

Go Number of Tools Used = ((Non-Productive Time-Loading and Unloading Time-(Tool Positioning Time per Operation*Number of Operations))*Batch Size-Basic Setup Time)/Setup Time per Tool

Non-productive time in turning

Go Non-Productive Time = ((Basic Setup Time+Number of Tools Used*Setup Time per Tool)/Batch Size)+Loading and Unloading Time+(Tool Positioning Time per Operation*Number of Operations)

Length of Cut using Machining Time

Go Length of Cut in Machining = Feed Rate in Machining*Machining Time in Machining*Rotational Frequency of Workpiece

Diameter of workpiece given Constant for Cylindrical Turning

Go Diameter of Workpiece = Constant For Machining Condition*Feed/(pi*Length of Cut)

Turning Length given Constant for Cylindrical Turning

Go Length of Cut = Constant For Machining Condition*Feed/(pi*Diameter of Workpiece)

Feed given Constant for Cylindrical Turning

Go Feed = pi*Diameter of Workpiece*Length of Cut/Constant For Machining Condition

Constant for given Cylindrical Turning

Go Constant For Machining Condition = pi*Diameter of Workpiece*Length of Cut/Feed

Feed Rate for Turning Operation given Machining Time

Go Feed Rate = Length of Cut/(Machining Time*Angular Velocity of Job or Workpiece)

Machining Time for Turning Operation

Go Machining Time = Length of Cut/(Feed Rate*Angular Velocity of Job or Workpiece)

Diameter of turned parts given Length-to-diameter Ratio

Go Diameter of Workpiece = (1.67/Length to Diameter Ratio)^(1/0.68)

Length-to-diameter Ratio given diameter of turned parts

Go Length to Diameter Ratio = 1.67/(Diameter of Workpiece^0.68)

Diameter of workpiece given Constant for Cylindrical Turning Formula

Diameter of Workpiece = Constant For Machining Condition*Feed/(pi*Length of Cut)
d_workpiece = K*f_in/(pi*L_cut)

Significance of Constant for Machining Operation

Constant for Machining Operation is the measure of accurate length the cutting tool works on a workpiece. Its value for different MAchining Operation such as Drilling, Milling is different even for similar jobs. It helps in determining the actual time for the tool engagement resulting in precise calculation of Tool Life.

How to Calculate Diameter of workpiece given Constant for Cylindrical Turning?

Diameter of workpiece given Constant for Cylindrical Turning calculator uses Diameter of Workpiece = Constant For Machining Condition*Feed/(pi*Length of Cut) to calculate the Diameter of Workpiece, Diameter of workpiece given Constant for Cylindrical Turning is a method to determine the maximum diameter of the workpiece that can be machined when Constant for Cylindrical Turning is bounded. Diameter of Workpiece is denoted by d_workpiece symbol.

How to calculate Diameter of workpiece given Constant for Cylindrical Turning using this online calculator? To use this online calculator for Diameter of workpiece given Constant for Cylindrical Turning, enter Constant For Machining Condition (K), Feed (f_in) & Length of Cut (L_cut) and hit the calculate button. Here is how the Diameter of workpiece given Constant for Cylindrical Turning calculation can be explained with given input values -> 38197.5 = 1.20001*0.0009/(pi*0.009).

FAQ

What is Diameter of workpiece given Constant for Cylindrical Turning?

Diameter of workpiece given Constant for Cylindrical Turning is a method to determine the maximum diameter of the workpiece that can be machined when Constant for Cylindrical Turning is bounded and is represented as d_workpiece = K*f_in/(pi*L_cut) or Diameter of Workpiece = Constant For Machining Condition*Feed/(pi*Length of Cut). Constant For Machining Condition can be regarded as the distance moved by the tool corner relative to the workpiece during a particular machining condition. It is usually measured in "Metre", The Feed is the distance the cutting tool advances along the length of the work for every revolution of the spindle & Length of cut (LOC) is a measurement of the functional cutting depth in the axial direction for a machining process.

How to calculate Diameter of workpiece given Constant for Cylindrical Turning?

Diameter of workpiece given Constant for Cylindrical Turning is a method to determine the maximum diameter of the workpiece that can be machined when Constant for Cylindrical Turning is bounded is calculated using Diameter of Workpiece = Constant For Machining Condition*Feed/(pi*Length of Cut). To calculate Diameter of workpiece given Constant for Cylindrical Turning, you need Constant For Machining Condition (K), Feed (f_in) & Length of Cut (L_cut). With our tool, you need to enter the respective value for Constant For Machining Condition, Feed & Length of Cut 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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