Power available for Machining given Initial weight of workpiece Calculator

✖Constant Power For Tool Type(a) is defined as the constant for the type of material used in the tool.ⓘ Constant Power For Tool Type(a) [a_p]			+10% -10%
✖Initial Work Piece Weight is defined as the weight of the work piece before undergoing machining operation.ⓘ Initial Work Piece Weight [W]			+10% -10%
✖Constant For Tool Type(b) is defined as the constant for the type of material used in the tool.ⓘ Constant For Tool Type(b) [b]			+10% -10%

✖Power Available for Machining is defined as the amount of power available during the machining process.ⓘ Power available for Machining given Initial weight of workpiece [P_m]

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Formula

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Power available for Machining given Initial weight of workpiece

Formula

`"P"_{"m"} = "a"_{"p"}*("W")^"b"`

Example

`"11.20002kW"="2900"*("12.79999kg")^"0.529999827884223"`

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Power available for Machining given Initial weight of workpiece Solution

STEP 0: Pre-Calculation Summary

Formula Used

Power Available For Machining = Constant Power For Tool Type(a)*(Initial Work Piece Weight)^Constant For Tool Type(b)
P_m = a_p*(W)^b
This formula uses 4 Variables

Variables Used

Power Available For Machining - (Measured in Watt) - Power Available for Machining is defined as the amount of power available during the machining process.
Constant Power For Tool Type(a) - Constant Power For Tool Type(a) is defined as the constant for the type of material used in the tool.
Initial Work Piece Weight - (Measured in Kilogram) - Initial Work Piece Weight is defined as the weight of the work piece before undergoing machining operation.
Constant For Tool Type(b) - Constant For Tool Type(b) is defined as the constant for the type of material used in the tool.

STEP 1: Convert Input(s) to Base Unit

Constant Power For Tool Type(a): 2900 --> No Conversion Required
Initial Work Piece Weight: 12.79999 Kilogram --> 12.79999 Kilogram No Conversion Required
Constant For Tool Type(b): 0.529999827884223 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

P_m = a_p*(W)^b --> 2900*(12.79999)^0.529999827884223

Evaluating ... ...

P_m = 11200.0229199237

STEP 3: Convert Result to Output's Unit

11200.0229199237 Watt -->11.2000229199237 Kilowatt (Check conversion here)

FINAL ANSWER

11.2000229199237 ≈ 11.20002 Kilowatt <-- Power Available For Machining

(Calculation completed in 00.020 seconds)

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Created by Parul Keshav

National Institute of Technology (NIT), Srinagar

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Verified by Rajat Vishwakarma

University Institute of Technology RGPV (UIT - RGPV), Bhopal

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< 19 Initial Weight of Workpiece Calculators

Initial weight of workpiece given Total rate for Machining and Operator

Go Initial Work Piece Weight = ((Total Rate of Machining and Operator-(Factor to Allow For Operator*Direct Labor Rate))*(2*Amortized Years*Number of Shifts)/(Constant For Tool Type(e)*Factor to Allow For Machining))^(1/Constant for Tool Type(f))

Direct labour Rate given Total rate for Machining and Operator

Go Direct Labor Rate = (Total Rate of Machining and Operator-((Factor to Allow For Machining*Constant For Tool Type(e)*Initial Work Piece Weight^Constant for Tool Type(f))/(2*Amortized Years*Number of Shifts)))/Factor to Allow For Operator

Total rate for Machining and Operator

Go Total Rate of Machining and Operator = ((Factor to Allow For Machining*Constant For Tool Type(e)*Initial Work Piece Weight^Constant for Tool Type(f))/(2*Amortized Years*Number of Shifts))+(Factor to Allow For Operator*Direct Labor Rate)

Initial weight of workpiece given Machining time for maximum power

Go Initial Work Piece Weight = ((Density of Work Piece*Constant For Tool Type(a)*Machining Time For Maximum Power)/(Proportion of Initial Volume*Specific Cutting Energy in Machining))^(1/(1-Constant For Tool Type(b)))

Proportion of Initial Volume of workpiece to be removed given Initial weight of workpiece

Go Proportion of Initial Volume = (Machining Time For Maximum Power*Density of Work Piece*Constant For Tool Type(a))/(Specific Cutting Energy in Machining*Initial Work Piece Weight^(1-Constant For Tool Type(b)))

Specific cutting energy given Initial weight of workpiece

Go 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)))

Density of Workpiece given Initial weight of workpiece

Go Density of Work Piece = (Proportion of Initial Volume*Specific Cutting Energy in Machining*Initial Work Piece Weight^(1-Constant For Tool Type(b)))/(Machining Time For Maximum Power*Constant For Tool Type(a))

Length of Workpiece given Machining time for maximum power

Go Length of Workpiece = (Machining Time For Maximum Power*Power Available For Machining)/(Specific Cutting Energy in Machining*pi*Diameter of Workpiece*Depth of Cut)

Constant for machine type b given Power available for Machining

Go Constant For Tool Type(b) = (ln(Power Available For Machining/Constant For Tool Type(a)))/(ln(Initial Work Piece Weight))

Power available for Machining given Initial weight of workpiece

Go Power Available For Machining = Constant Power For Tool Type(a)*(Initial Work Piece Weight)^Constant For Tool Type(b)

Initial weight of workpiece given Cost of Machine tool

Go Initial Work Piece Weight For Machine Tool = (Cost of A Tool/Constant For Tool Type(e))^(1/Constant for Tool Type(f))

Initial weight of workpiece given Power available for Machining

Go Initial Work Piece Weight = (Power Available For Machining/Constant For Tool Type(a))^(1/Constant For Tool Type(b))

Constant for machine type given Power available for Machining

Go Constant For Tool Type(a) = Power Available For Machining/(Initial Work Piece Weight)^Constant For Tool Type(b)

Loading and Unloading time given initial weight of workpiece

Go Loading And Unloading Time = Constant For Tool Type(c)+(Constant For Tool Type(d)*Initial Work Piece Weight)

Initial weight of workpiece given Loading and Unloading time

Go Initial Work Piece Weight = (Loading And Unloading Time-Constant For Tool Type(c))/Constant For Tool Type(d)

Surface area of Workpiece given Surface Generation rate

Go Surface Area of Workpiece = (Machining Surface Generation Time For Minimum Cost*Surface Generation Rate)

Initial weight of workpiece given Machining time under Max power for free machining

Go Initial Work Piece Weight For Free Machining = (Machining Time For Maximum Power/49.9)^(1/0.47)

Initial weight of workpiece given Length-to-diameter Ratio

Go Initial Work Piece Weight = (1.26/Length to Diameter Ratio)^(1/0.29)

Length-to-diameter Ratio in terms Initial weight of workpiece

Go Length to Diameter Ratio = 1.26/(Initial Work Piece Weight^0.29)

Power available for Machining given Initial weight of workpiece Formula

Power Available For Machining = Constant Power For Tool Type(a)*(Initial Work Piece Weight)^Constant For Tool Type(b)
P_m = a_p*(W)^b

How much power does a CNC machine use?

The Energy Efficient CNC, DATRON M7 with a 1.8 kwatt spindle, draws approximately 1.0 kwatt hour. Calculated on 60% power consumption, a continuous 40-hour workweek at an average state rate of $0.1472 per kwatt; the M7 costs approximately $197 a month to power.

How to Calculate Power available for Machining given Initial weight of workpiece?

Power available for Machining given Initial weight of workpiece calculator uses Power Available For Machining = Constant Power For Tool Type(a)*(Initial Work Piece Weight)^Constant For Tool Type(b) to calculate the Power Available For Machining, The Power available for Machining given Initial weight of workpiece is defined as the amount of power available during the machining process. Power Available For Machining is denoted by P_m symbol.

How to calculate Power available for Machining given Initial weight of workpiece using this online calculator? To use this online calculator for Power available for Machining given Initial weight of workpiece, enter Constant Power For Tool Type(a) (a_p), Initial Work Piece Weight (W) & Constant For Tool Type(b) (b) and hit the calculate button. Here is how the Power available for Machining given Initial weight of workpiece calculation can be explained with given input values -> 0.0112 = 2900*(12.79999)^0.529999827884223.

FAQ

What is Power available for Machining given Initial weight of workpiece?

The Power available for Machining given Initial weight of workpiece is defined as the amount of power available during the machining process and is represented as P_m = a_p*(W)^b or Power Available For Machining = Constant Power For Tool Type(a)*(Initial Work Piece Weight)^Constant For Tool Type(b). Constant Power For Tool Type(a) is defined as the constant for the type of material used in the tool, Initial Work Piece Weight is defined as the weight of the work piece before undergoing machining operation & Constant For Tool Type(b) is defined as the constant for the type of material used in the tool.

How to calculate Power available for Machining given Initial weight of workpiece?

The Power available for Machining given Initial weight of workpiece is defined as the amount of power available during the machining process is calculated using Power Available For Machining = Constant Power For Tool Type(a)*(Initial Work Piece Weight)^Constant For Tool Type(b). To calculate Power available for Machining given Initial weight of workpiece, you need Constant Power For Tool Type(a) (a_p), Initial Work Piece Weight (W) & Constant For Tool Type(b) (b). With our tool, you need to enter the respective value for Constant Power For Tool Type(a), Initial Work Piece Weight & Constant For Tool Type(b) 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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