11 Other formulas that you can solve using the same Inputs

Torque In Running Condition
Torque=3*Slip*Electromotive Force*Electromotive Force*Resistance/(2*pi*Synchronous Speed*((Resistance*Resistance)+(Reactance*Reactance*Slip))) GO
Mechanical Power Of When Input Power Is Given
Mechanical Power=Input Power-(Armature Current*Armature Current*Armature resistance) GO
Efficiency of Machine
Gear Efficiency=Output Power/Input Power GO
Synchronous Speed When Motor Speed Is Given
Synchronous Speed=Motor Speed/(1-Slip) GO
Motor Speed
Motor Speed=Synchronous Speed*(1-Slip) GO
Power Loss
Power Loss=Input Power-Output Power GO
Slip When The Copper Loss Is Given
Slip=Rotor Cu Loss*Input Power GO
Rotor Copper Loss
Rotor Cu Loss=Slip*Input Power GO
Resistance When Slip Is Given
Resistance=Slip*Reactance GO
Reactance When Slip Is Given
Reactance=Resistance/Slip GO
Motor Efficiency Using Slip
Efficiency =1-Slip GO

11 Other formulas that calculate the same Output

Power transmittted by a belt
Power=(Tensions in the tight side of belt-Tensions in the slack side of belt)* Velocity of the belt GO
Power In Single-Phase AC Circuits When Current Is Given
Power=Electric Current*Electric Current*Resistance*cos(Theta) GO
Power when electric potential difference and electric current are given
Power=Electric Potential Difference*Electric Current GO
Power, when electric potential difference and resistance are given,
Power=Electric Potential Difference^2/Resistance GO
Power in Single-Phase AC Circuits When Voltage is Given
Power=(Voltage*Voltage*cos(Theta))/Resistance GO
Power In Single-Phase AC Circuits
Power=Voltage*Electric Current*cos(Theta) GO
Power Generated When The Armature Current Is Given
Power=Induced voltage*Armature Current GO
Converted Power
Power=Induced voltage*Armature Current GO
Power, when electric current and resistance are given
Power=(Electric Current)^2*Resistance GO
Power Generated When Torque is Given
Power=Angular Speed*Torque GO
Output Power
Power=Voltage*Load current GO

Gross Mechanical Power Formula

Power=(1-Slip)*Input Power
More formulas
Force GO
Synchronous Speed GO
Slip GO
Motor Speed GO
Slip When Frequency Is Given GO
Rotor Efficiency GO
Motor Efficiency Using Slip GO
Slip Of Linear Synchronous Motor GO
Force By A Linear Induction Motor GO
Rotor Copper Loss GO
Starting Torque of Inductance Motor GO
Torque In Running Condition GO
Maximum Running Torque GO
Breakdown Slip Of An Induction Motor GO
Slip When Efficiency Is Given GO
Motor Speed When Efficiency Is Given GO
Synchronous Speed When Efficiency Is Given GO
Slip When The Copper Loss Is Given GO
Resistance When Slip Is Given GO
Reactance When Slip Is Given GO
Voltage GO
Gross Torque When Synchronous Speed Is Given GO
Synchronous Speed When Mechanical Power Is Given GO
Gross Torque When Mechanical Power Is Given GO
Synchronous Speed When Gross Torque Is Given GO
Field Current When Load Current Is Given GO
Load Current GO
Induced Voltage When Power Is Given GO
Armature Current When Power Is Given GO
Motor Speed When Angular Speed Is Given GO
Synchronous Speed When Motor Speed Is Given GO
Slip When Input Power Is Given GO
Number Of Poles When Synchronous Speed Is Given GO
Frequency When The Number of Poles Is Given GO

What is Mechanical Loss?

Mechanical losses occur at the bearing and brush friction loss occurs in the wound rotor induction motor. These losses are zero at the start and with an increase in speed these losses increase. In a three-phase induction motor, the speed usually remains constant. Hence these losses almost remain constant.

How to Calculate Gross Mechanical Power?

Gross Mechanical Power calculator uses Power=(1-Slip)*Input Power to calculate the Power, Gross Mechanical Power or gross electric output is the total amount of electricity generated by a power plant over a specific period of time. Power and is denoted by P symbol.

How to calculate Gross Mechanical Power using this online calculator? To use this online calculator for Gross Mechanical Power, enter Input Power (Pin) and Slip (s) and hit the calculate button. Here is how the Gross Mechanical Power calculation can be explained with given input values -> 38.4 = (1-0.04)*40.

FAQ

What is Gross Mechanical Power?
Gross Mechanical Power or gross electric output is the total amount of electricity generated by a power plant over a specific period of time and is represented as P=(1-s)*Pin or Power=(1-Slip)*Input Power. Input Power is the power, which is required by the appliance at its input i.e., from the plug point and Slip is the difference between synchronous speed and the actual speed of the induction motor.
How to calculate Gross Mechanical Power?
Gross Mechanical Power or gross electric output is the total amount of electricity generated by a power plant over a specific period of time is calculated using Power=(1-Slip)*Input Power. To calculate Gross Mechanical Power, you need Input Power (Pin) and Slip (s). With our tool, you need to enter the respective value for Input Power and Slip 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?
In this formula, Power uses Input Power and Slip. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Power=Electric Potential Difference*Electric Current
  • Power=(Electric Current)^2*Resistance
  • Power=Electric Potential Difference^2/Resistance
  • Power=Angular Speed*Torque
  • Power=Induced voltage*Armature Current
  • Power=Voltage*Load current
  • Power=Induced voltage*Armature Current
  • Power=(Tensions in the tight side of belt-Tensions in the slack side of belt)* Velocity of the belt
  • Power=Voltage*Electric Current*cos(Theta)
  • Power=Electric Current*Electric Current*Resistance*cos(Theta)
  • Power=(Voltage*Voltage*cos(Theta))/Resistance
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