Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation Calculator

✖The Total Rate of Heat Generation in Metal Cutting is defined as the total amount of heat generated due to friction and disturbances & losses while metal cutting.ⓘ Total Rate of Heat Generation in Metal Cutting [P_m]			+10% -10%
✖Rate of Heat Transportation By Chip is defined as the amount of heat transported by the chip.ⓘ Rate of Heat Transportation By Chip [Φ_c]			+10% -10%
✖Rate of Heat Conduction into The Tool is defined as the amount of heat transferred into the tool with conduction while metal cutting.ⓘ Rate of Heat Conduction into The Tool [Φ_t]			+10% -10%

✖Rate of Heat Conduction into The Workpiece is defined as the rate of heat transferred into the workpiece with conduction.ⓘ Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation [Φ_w]

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Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation Solution

STEP 0: Pre-Calculation Summary

Formula Used

Rate of Heat Conduction into The Workpiece = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Transportation By Chip-Rate of Heat Conduction into The Tool
Φ_w = P_m-Φ_c-Φ_t
This formula uses 4 Variables

Variables Used

Rate of Heat Conduction into The Workpiece - (Measured in Watt) - Rate of Heat Conduction into The Workpiece is defined as the rate of heat transferred into the workpiece with conduction.
Total Rate of Heat Generation in Metal Cutting - (Measured in Watt) - The Total Rate of Heat Generation in Metal Cutting is defined as the total amount of heat generated due to friction and disturbances & losses while metal cutting.
Rate of Heat Transportation By Chip - (Measured in Watt) - Rate of Heat Transportation By Chip is defined as the amount of heat transported by the chip.
Rate of Heat Conduction into The Tool - (Measured in Watt) - Rate of Heat Conduction into The Tool is defined as the amount of heat transferred into the tool with conduction while metal cutting.

STEP 1: Convert Input(s) to Base Unit

Total Rate of Heat Generation in Metal Cutting: 108 Watt --> 108 Watt No Conversion Required
Rate of Heat Transportation By Chip: 54 Watt --> 54 Watt No Conversion Required
Rate of Heat Conduction into The Tool: 16 Watt --> 16 Watt No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

Φ_w = P_m-Φ_c-Φ_t --> 108-54-16

Evaluating ... ...

Φ_w = 38

STEP 3: Convert Result to Output's Unit

38 Watt --> No Conversion Required

FINAL ANSWER

38 Watt <-- Rate of Heat Conduction into The Workpiece

(Calculation completed in 00.004 seconds)

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Created by Parul Keshav

National Institute of Technology (NIT), Srinagar

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

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< Heat Conduction Rate Calculators

Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation

LaTeX Go Rate of Heat Conduction into The Workpiece = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Transportation By Chip-Rate of Heat Conduction into The Tool

Rate of Heat Transportation by Chip given Total Rate of Heat Generation

LaTeX Go Rate of Heat Transportation By Chip = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Conduction into The Workpiece-Rate of Heat Conduction into The Tool

Rate of Heat Conduction into Tool given Total Rate of Heat Generation

LaTeX Go Rate of Heat Conduction into The Tool = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Transportation By Chip-Rate of Heat Conduction into The Workpiece

Rate of Energy Consumption using Rate of Heat Generation during Machining

LaTeX Go Rate of Energy Consumption During Machining = Rate of Heat Generation in Primary Shear Zone+Rate of Heat Generation in Secondary Shear Zone

Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation Formula

LaTeX Go

Rate of Heat Conduction into The Workpiece = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Transportation By Chip-Rate of Heat Conduction into The Tool
Φ_w = P_m-Φ_c-Φ_t

How can heat generated in metal cutting be determined?

Heat is generated in three ways; by the deformation of the metal in the shear zone ahead of the cutting edge, at the point of separation when the metal is physically pulled apart, and by the friction of the chip as it rubs along the surface of the tool as it is pushed out of the way.

How to Calculate Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation?

Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation calculator uses Rate of Heat Conduction into The Workpiece = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Transportation By Chip-Rate of Heat Conduction into The Tool to calculate the Rate of Heat Conduction into The Workpiece, The Rate of Heat Conduction into Workpiece given Total rate of Heat Generation is the rate of heat being transferred into the workpiece while the metal cutting process. Rate of Heat Conduction into The Workpiece is denoted by Φ_w symbol.

How to calculate Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation using this online calculator? To use this online calculator for Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation, enter Total Rate of Heat Generation in Metal Cutting (P_m), Rate of Heat Transportation By Chip (Φ_c) & Rate of Heat Conduction into The Tool (Φ_t) and hit the calculate button. Here is how the Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation calculation can be explained with given input values -> 38 = 108-54-16.

FAQ

What is Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation?

The Rate of Heat Conduction into Workpiece given Total rate of Heat Generation is the rate of heat being transferred into the workpiece while the metal cutting process and is represented as Φ_w = P_m-Φ_c-Φ_t or Rate of Heat Conduction into The Workpiece = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Transportation By Chip-Rate of Heat Conduction into The Tool. The Total Rate of Heat Generation in Metal Cutting is defined as the total amount of heat generated due to friction and disturbances & losses while metal cutting, Rate of Heat Transportation By Chip is defined as the amount of heat transported by the chip & Rate of Heat Conduction into The Tool is defined as the amount of heat transferred into the tool with conduction while metal cutting.

How to calculate Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation?

The Rate of Heat Conduction into Workpiece given Total rate of Heat Generation is the rate of heat being transferred into the workpiece while the metal cutting process is calculated using Rate of Heat Conduction into The Workpiece = Total Rate of Heat Generation in Metal Cutting-Rate of Heat Transportation By Chip-Rate of Heat Conduction into The Tool. To calculate Rate of Heat Conduction into Workpiece given Total Rate of Heat Generation, you need Total Rate of Heat Generation in Metal Cutting (P_m), Rate of Heat Transportation By Chip (Φ_c) & Rate of Heat Conduction into The Tool (Φ_t). With our tool, you need to enter the respective value for Total Rate of Heat Generation in Metal Cutting, Rate of Heat Transportation By Chip & Rate of Heat Conduction into The Tool 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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