Urvi Rathod
Vishwakarma Government Engineering College (VGEC), Ahmedabad
Urvi Rathod has created this Calculator and 500+ more calculators!
Kethavath Srinath
Osmania University (OU), Hyderabad
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11 Other formulas that you can solve using the same Inputs

voltage using Overall Efficiency Of Dc Motor
Voltage=((((Electric Current-Shunt Field Current)^2)*Armature resistance)+Mechanical Losses+Core Losses)/(Electric Current*(1-Overall Efficiency From Shaft A to X)) GO
Shunt Field Current Using Overall Efficiency Of Dc Motor
Shunt Field Current=sqrt(((Voltage*Electric Current)*(1-Overall Efficiency From Shaft A to X)-Mechanical Losses-Core Losses)/Armature resistance) GO
Current Using Overall Efficiency Of Dc Motor
Electric Current=(((Shunt Field Current^2)*Armature resistance)+Mechanical Losses+Core Losses)/(Voltage*(1-Overall Efficiency From Shaft A to X)) GO
Armature Resistance using Overall Efficiency Of Dc Motor
Armature resistance=((Voltage*Electric Current)*(1-Overall Efficiency From Shaft A to X)-Mechanical Losses-Core Losses)/(Shunt Field Current^2) GO
Armature Copper Loss Using Overall Efficiency Of Dc Motor
Armature Copper Loss=Input Power-(Overall Efficiency From Shaft A to X*Input Power)-Mechanical Power-Core Losses-Field Cu Losses GO
field copper loss using Overall Efficiency Of Dc Motor
Field Cu Losses=Input Power-(Overall Efficiency From Shaft A to X*Input Power)-Mechanical Power-Core Losses-Armature Copper Loss GO
mechanical Losses Of Series DC Generator Using Converted Power
Mechanical Losses=Input Power-Core Losses-Stray Losses-Converted Power GO
The Stray Losses Of Series DC Generator Using Converted Power
Stray Losses=Input Power-Mechanical Losses-Core Losses-Converted Power GO
Converted Power Of Series DC Generator Using Input Power
Converted Power=Input Power-Stray Losses-Mechanical Losses-Core Losses GO
Core Losses Of Series DC Generator Using Converted Power
Core Losses=Input Power-Mechanical Losses-Converted Power-Stray Losses GO
Core Loss Using Overall Efficiency Of Dc Motor
Core Losses=Power Loss-Mechanical Losses GO

11 Other formulas that calculate the same Output

Losses Using Transmission Efficiency (STL)
Power Loss=((3*Receiving end voltage *Receiving end current *cos(Receiving end theta))/Transmission efficiency)-(3*Receiving end voltage *Receiving end current *cos(Receiving end theta)) GO
Losses Using Sending and Receiving Voltages (STL)
Power Loss=(Sending End Voltage*Sending end current *cos(Sending end theta))-(Receiving end voltage *Receiving end current *cos(Receiving end theta)) GO
Losses (Nominal T-method)
Power Loss=3*(Resistance/2)*((Receiving end current ^2)+(Sending end current ^2)) GO
Losses Using Transmission Efficiency (Nominal pi-method)
Power Loss=(Receiving End Power/Transmission efficiency)-Receiving End Power GO
Losses Using Transmission Efficiency (Nominal T-method)
Power Loss=(Receiving End Power/Transmission efficiency)-Receiving End Power GO
Losses Using Transmission Efficiency(ECM)
Power Loss=(Receiving End Power/Transmission efficiency)-Receiving End Power GO
Total Loss Power Using Overall Efficiency Of Dc Motor
Power Loss=Input Power-Overall Efficiency From Shaft A to X*Input Power GO
Losses Using Sending End Power (Nominal pi-method)
Power Loss=Sending End Power-Receiving End Power GO
Losses Using Sending End Power (Nominal T-method)
Power Loss=Sending End Power-Receiving End Power GO
Losses (Nominal pi-method)
Power Loss=3*(Load current^2)*Resistance GO
Power Loss
Power Loss=Input Power-Output Power GO

Constant Losses Using Overall Efficiency Of Dc Motor Formula

Power Loss=Core Losses+Mechanical Losses
P<sub>loss</sub>=Lc+Lm
More formulas
Electrical Efficiency Of Dc Motor GO
Mechanical Efficiency Of Dc Motor GO
Overall Efficiency Of Dc Motor GO
Voltage Using Electrical Efficiency Of Dc Motor GO
Angular Speed Using Electrical Efficiency Of Dc Motor GO
Armature Current Using Electrical Efficiency Of Dc Motor GO
Armature Torque Using Electrical Efficiency Of Dc Motor GO
input power using Electrical Efficiency Of Dc Motor GO
Converted Power Using Mechanical Efficiency Of Dc Motor GO
Output Power Using Mechanical Efficiency Of Dc Motor GO
armature torque using mechanical Efficiency Of Dc Motor GO
Converted Power Using Electrical Efficiency Of Dc Motor GO
Torque Using Mechanical Efficiency Of Dc Motor GO
output power using Overall Efficiency Of Dc Motor GO
Input Power using Overall Efficiency Of Dc Motor GO
Armature Copper Loss Using Overall Efficiency Of Dc Motor GO
field copper loss using Overall Efficiency Of Dc Motor GO
voltage using Overall Efficiency Of Dc Motor GO
Current Using Overall Efficiency Of Dc Motor GO
Shunt Field Current Using Overall Efficiency Of Dc Motor GO
Armature Resistance using Overall Efficiency Of Dc Motor GO
Total Loss Power Using Overall Efficiency Of Dc Motor GO
Core Loss Using Overall Efficiency Of Dc Motor GO
Mechanical Loss Using Overall Efficiency Of Dc Motor GO

What is the definition of efficiency?

Efficiency signifies a peak level of performance that uses the least amount of inputs to achieve the highest amount of output. Efficiency requires reducing the number of unnecessary resources used to produce a given output including personal time and energy.

How to Calculate Constant Losses Using Overall Efficiency Of Dc Motor?

Constant Losses Using Overall Efficiency Of Dc Motor calculator uses Power Loss=Core Losses+Mechanical Losses to calculate the Power Loss, The constant losses using Overall Efficiency Of Dc Motor formula are defined as the loss of the DC motor that does not change with load. Power Loss and is denoted by Ploss symbol.

How to calculate Constant Losses Using Overall Efficiency Of Dc Motor using this online calculator? To use this online calculator for Constant Losses Using Overall Efficiency Of Dc Motor, enter Core Losses (Lc) and Mechanical Losses (Lm) and hit the calculate button. Here is how the Constant Losses Using Overall Efficiency Of Dc Motor calculation can be explained with given input values -> 17 = 7+10.

FAQ

What is Constant Losses Using Overall Efficiency Of Dc Motor?
The constant losses using Overall Efficiency Of Dc Motor formula are defined as the loss of the DC motor that does not change with load and is represented as Ploss=Lc+Lm or Power Loss=Core Losses+Mechanical Losses. core losses are the same as the Iron losses and Mechanical Losses is the losses associated with the mechanical friction of the machine.
How to calculate Constant Losses Using Overall Efficiency Of Dc Motor?
The constant losses using Overall Efficiency Of Dc Motor formula are defined as the loss of the DC motor that does not change with load is calculated using Power Loss=Core Losses+Mechanical Losses. To calculate Constant Losses Using Overall Efficiency Of Dc Motor, you need Core Losses (Lc) and Mechanical Losses (Lm). With our tool, you need to enter the respective value for Core Losses and Mechanical Losses 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 Power Loss?
In this formula, Power Loss uses Core Losses and Mechanical Losses. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Power Loss=Input Power-Output Power
  • Power Loss=Input Power-Overall Efficiency From Shaft A to X*Input Power
  • Power Loss=((3*Receiving end voltage *Receiving end current *cos(Receiving end theta))/Transmission efficiency)-(3*Receiving end voltage *Receiving end current *cos(Receiving end theta))
  • Power Loss=(Sending End Voltage*Sending end current *cos(Sending end theta))-(Receiving end voltage *Receiving end current *cos(Receiving end theta))
  • Power Loss=(Receiving End Power/Transmission efficiency)-Receiving End Power
  • Power Loss=3*(Load current^2)*Resistance
  • Power Loss=Sending End Power-Receiving End Power
  • Power Loss=Sending End Power-Receiving End Power
  • Power Loss=3*(Resistance/2)*((Receiving end current ^2)+(Sending end current ^2))
  • Power Loss=(Receiving End Power/Transmission efficiency)-Receiving End Power
  • Power Loss=(Receiving End Power/Transmission efficiency)-Receiving End Power
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