Armature Resistance Of Series DC Motor Using Voltage Calculator

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✖Voltage, electric potential difference, electric pressure, or electric tension is the difference in electric potential between two points, which is defined as the work needed per unit of charge to move a test charge between the two points.ⓘ Voltage [V]			+10% -10%
✖Induced voltage when reactive power is given is the difference in electric potential between two points.ⓘ Induced voltage [Ea]			+10% -10%
✖Armature Current is the Current which Flows in Armature Winding or rotating Winding of Motor or generator.ⓘ Armature Current [Ia]			+10% -10%
✖Series field resistance is resistance just like the filed resistance but it is connected to a series field.ⓘ Series field resistance [Rse]			+10% -10%

✖The Armature resistance is given is the opposition that a substance offers to the flow of electric current.ⓘ Armature Resistance Of Series DC Motor Using Voltage [Ra]

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Armature Resistance Of Series DC Motor Using Voltage

Urvi Rathod

Vishwakarma Government Engineering College (VGEC), Ahmedabad

Urvi Rathod has created this Calculator and 500+ more calculators!

Kethavath Srinath

Osmania University (OU), Hyderabad

Kethavath Srinath has verified this Calculator and 500+ more calculators!

< 11 Other formulas that you can solve using the same Inputs

Series Generator Terminal Voltage

Voltage=Induced voltage-(Armature Current*(Armature resistance+Series field resistance)) GO

Back EMF

Electromotive Force=Voltage-(Armature Current*Armature resistance) GO

Shunt Generator Terminal Voltage

Voltage=Induced voltage-(Armature Current*Armature resistance) GO

Velocity of an electron due to voltage

Velocity due to voltage=((2*[Charge-e]*Voltage)/[Mass-e])^1/2 GO

Energy Stored in Capacitor when Capacitance and Voltage are Given

electrostatic potential energy=1/2*Capacitance*Voltage^2 GO

Shunt Field Current

Shunt Field Current=Voltage/Shunt field resistance GO

Energy Stored in Capacitor when Charge and Voltage are Given

electrostatic potential energy=1/2*Charge*Voltage GO

Capacitance

Capacitance=dielectric constant*Charge/Voltage GO

Field Current

Field Current=Voltage/Shunt field resistance GO

Power Generated When The Armature Current Is Given

Power=Induced voltage*Armature Current GO

Output Power

Power=Voltage*Load current GO

< 6 Other formulas that calculate the same Output

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 resistance Of Synchronous Motor Using 3-phase Mechanical Power

Armature resistance=(Input Power-Mechanical Power)/(3*Armature Current*Armature Current) GO

Armature Resistance Of Synchronous Motor Using The Mechanical Power

Armature resistance=(Input Power-Mechanical Power)/Armature Current*Armature Current GO

Armature Resistance Of Synchronous Motor Using Input Power

Armature resistance=(Input Power-Mechanical Power)/Armature Current*Armature Current GO

Armature Resistance Of Series DC Generator Using Voltage

Armature resistance=((Induced voltage-Voltage)/Armature Current)-Series resistor GO

Armature Resistance Of Shunt DC Motor Using Voltage

Armature resistance=(Voltage-Back emf)/Armature Current GO

Armature Resistance Of Series DC Motor Using Voltage Formula

Armature resistance=((Voltage-Induced voltage)/Armature Current)-Series field resistance
Ra=((V-Ea)/Ia)-Rse

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Voltage Equation Of Series DC Motor GO

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Armature Current Of Series DC Motor Using Voltage GO

Series Field Resistance Of Series DC Motor Using Voltage GO

Armature Induced Voltage Of Series DC Motor Using Kf GO

Magnetic Flux Of Series DC Motor Using Kf GO

Angular Speed Of Series DC Motor Using Kf GO

Armature Current Of Series DC Motor Using Kf GO

Kf of Series DC Motor Using Armature Induced Voltage GO

Torque Of Series DC Motor Using Kf GO

Kf Of Series DC Motor Using Torque GO

Magnetic Flux Of Series DC motor Using Torque GO

Armature Current Of Series DC Motor Using Torque GO

Speed Of Series DC Motor GO

Voltage Of Series DC Motor Using Speed GO

Armature Current Of Series DC Motor Using Speed GO

Series Field Resistance Of Series DC Motor Using Speed GO

K of Series DC Motor Using Speed GO

Magnetic Flux Of Series DC Motor Using Speed GO

Input Power Of Series DC Motor GO

Output Power Of Series DC Motor GO

Voltage Of Series DC Motor Using Input Power GO

Armature Current Of Series DC Motor Using Input Power GO

Angular Speed Of Series DC Motor Using Output Power GO

Torque Of Series DC Motor Using Output Power GO

What is a series DC motor?

A series wound DC motor like in the case of shunt wound DC motor or compound wound DC motor falls under the category of self-excited DC motors, and it gets its name from the fact that the field winding, in this case, is connected internally in series to the armature winding.

How to Calculate Armature Resistance Of Series DC Motor Using Voltage?

Armature Resistance Of Series DC Motor Using Voltage calculator uses Armature resistance=((Voltage-Induced voltage)/Armature Current)-Series field resistance to calculate the Armature resistance, The Armature Resistance Of Series DC Motor Using Voltage formula is defined as the resistance of the armature winding of the series dc motor. Armature resistance and is denoted by Ra symbol.

How to calculate Armature Resistance Of Series DC Motor Using Voltage using this online calculator? To use this online calculator for Armature Resistance Of Series DC Motor Using Voltage, enter Voltage (V), Induced voltage (Ea), Armature Current (Ia) and Series field resistance (Rse) and hit the calculate button. Here is how the Armature Resistance Of Series DC Motor Using Voltage calculation can be explained with given input values -> 130 = ((120-50)/0.5)-10.

FAQ

What is Armature Resistance Of Series DC Motor Using Voltage?

The Armature Resistance Of Series DC Motor Using Voltage formula is defined as the resistance of the armature winding of the series dc motor and is represented as Ra=((V-Ea)/Ia)-Rse or Armature resistance=((Voltage-Induced voltage)/Armature Current)-Series field resistance. Voltage, electric potential difference, electric pressure, or electric tension is the difference in electric potential between two points, which is defined as the work needed per unit of charge to move a test charge between the two points, Induced voltage when reactive power is given is the difference in electric potential between two points, Armature Current is the Current which Flows in Armature Winding or rotating Winding of Motor or generator and Series field resistance is resistance just like the filed resistance but it is connected to a series field.

How to calculate Armature Resistance Of Series DC Motor Using Voltage?

The Armature Resistance Of Series DC Motor Using Voltage formula is defined as the resistance of the armature winding of the series dc motor is calculated using Armature resistance=((Voltage-Induced voltage)/Armature Current)-Series field resistance. To calculate Armature Resistance Of Series DC Motor Using Voltage, you need Voltage (V), Induced voltage (Ea), Armature Current (Ia) and Series field resistance (Rse). With our tool, you need to enter the respective value for Voltage, Induced voltage, Armature Current and Series field resistance 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 Armature resistance?

In this formula, Armature resistance uses Voltage, Induced voltage, Armature Current and Series field resistance. We can use 6 other way(s) to calculate the same, which is/are as follows -

Armature resistance=((Induced voltage-Voltage)/Armature Current)-Series resistor
Armature resistance=(Voltage-Back emf)/Armature Current
Armature resistance=(Input Power-Mechanical Power)/Armature Current*Armature Current
Armature resistance=(Input Power-Mechanical Power)/Armature Current*Armature Current
Armature resistance=(Input Power-Mechanical Power)/(3*Armature Current*Armature Current)
Armature resistance=((Voltage*Electric Current)*(1-Overall Efficiency From Shaft A to X)-Mechanical Losses-Core Losses)/(Shunt Field Current^2)

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