Induced EMF given Linear Synchronous Speed Calculator

✖Linear Synchronous Speed is the synchronous speed of the linear synchronous machine.ⓘ Linear Synchronous Speed [V_s]			+10% -10%
✖Magnetic Flux Density is defined as the number of lines of force passing through a unit area of material.ⓘ Magnetic Flux Density [B]			+10% -10%
✖Length of Conductor is the net length of conductor present in the magnetic field.ⓘ Length of Conductor [l]			+10% -10%

✖Induced EMF is the EMF generated due to the motion.ⓘ Induced EMF given Linear Synchronous Speed [E_i]

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Formula

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Induced EMF given Linear Synchronous Speed

Formula

`"E"_{"i"} = "V"_{"s"}*"B"*"l"`

Example

`"4.8654V"="135m/s"*"0.68T"*"53mm"`

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Induced EMF given Linear Synchronous Speed Solution

STEP 0: Pre-Calculation Summary

Formula Used

Induced EMF = Linear Synchronous Speed*Magnetic Flux Density*Length of Conductor
E_i = V_s*B*l
This formula uses 4 Variables

Variables Used

Induced EMF - (Measured in Volt) - Induced EMF is the EMF generated due to the motion.
Linear Synchronous Speed - (Measured in Meter per Second) - Linear Synchronous Speed is the synchronous speed of the linear synchronous machine.
Magnetic Flux Density - (Measured in Tesla) - Magnetic Flux Density is defined as the number of lines of force passing through a unit area of material.
Length of Conductor - (Measured in Meter) - Length of Conductor is the net length of conductor present in the magnetic field.

STEP 1: Convert Input(s) to Base Unit

Linear Synchronous Speed: 135 Meter per Second --> 135 Meter per Second No Conversion Required
Magnetic Flux Density: 0.68 Tesla --> 0.68 Tesla No Conversion Required
Length of Conductor: 53 Millimeter --> 0.053 Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

E_i = V_s*B*l --> 135*0.68*0.053

Evaluating ... ...

E_i = 4.8654

STEP 3: Convert Result to Output's Unit

4.8654 Volt --> No Conversion Required

FINAL ANSWER

4.8654 Volt <-- Induced EMF

(Calculation completed in 00.004 seconds)

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Vishwakarma Government Engineering College (VGEC), Ahmedabad

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< 2 Voltage & EMF Calculators

Induced EMF given Linear Synchronous Speed

Go Induced EMF = Linear Synchronous Speed*Magnetic Flux Density*Length of Conductor

Induced Voltage given Power

Go Armature Voltage = Output Power/Armature Current

< 25 Induction Motor Circuit Calculators

Torque of Induction Motor under Running Condition

Go Torque = (3*Slip*EMF^2*Resistance)/(2*pi*Synchronous Speed*(Resistance^2+(Reactance^2*Slip)))

Rotor Current in Induction Motor

Go Rotor Current = (Slip*Induced EMF)/sqrt(Rotor Resistance per Phase^2+(Slip*Rotor Reactance per Phase)^2)

Starting Torque of Induction Motor

Go Torque = (3*EMF^2*Resistance)/(2*pi*Synchronous Speed*(Resistance^2+Reactance^2))

Maximum Running Torque

Go Running Torque = (3*EMF^2)/(4*pi*Synchronous Speed*Reactance)

Linear Synchronous Speed

Go Linear Synchronous Speed = 2*Pole Pitch Width*Line Frequency

Stator Copper Loss in Induction Motor

Go Stator Copper Loss = 3*Stator Current^2*Stator Resistance

Rotor Copper Loss in Induction Motor

Go Rotor Copper Loss = 3*Rotor Current^2*Rotor Resistance

Synchronous Speed in Induction Motor

Go Synchronous Speed = (120*Frequency)/(Number of Poles)

Frequency given Number of Poles in Induction Motor

Go Frequency = (Number of Poles*Synchronous Speed)/120

Armature Current given Power in Induction Motor

Go Armature Current = Output Power/Armature Voltage

Synchronous Speed of Induction Motor given Efficiency

Go Synchronous Speed = (Motor Speed)/(Efficiency)

Rotor Efficiency in Induction Motor

Go Efficiency = (Motor Speed)/(Synchronous Speed)

Field Current using Load Current in Induction Motor

Go Field Current = Armature Current-Load Current

Rotor Input Power in Induction Motor

Go Rotor Input Power = Input Power-Stator Losses

Load Current in Induction Motor

Go Load Current = Armature Current-Field Current

Force by Linear Induction Motor

Go Force = Input Power/Linear Synchronous Speed

Motor Speed given Efficiency in Induction Motor

Go Motor Speed = Efficiency*Synchronous Speed

Rotor Copper Loss given Input Rotor Power

Go Rotor Copper Loss = Slip*Rotor Input Power

Pitch Factor in Induction Motor

Go Pitch Factor = cos(Short Pitched Angle/2)

Gross Mechanical Power in Induction Motor

Go Mechanical Power = (1-Slip)*Input Power

Rotor Frequency given Supply Frequency

Go Rotor Frequency = Slip*Frequency

Resistance given Slip at Maximum Torque

Go Resistance = Slip*Reactance

Reactance given Slip at Maximum Torque

Go Reactance = Resistance/Slip

Breakdown Slip of Induction Motor

Go Slip = Resistance/Reactance

Slip given Efficiency in Induction Motor

Go Slip = 1-Efficiency

Induced EMF given Linear Synchronous Speed Formula

Induced EMF = Linear Synchronous Speed*Magnetic Flux Density*Length of Conductor
E_i = V_s*B*l

What is voltage induced electric field?

A voltage-induced electric field is when a capacitor or condenser is charged with a direct current and a positive charge on one plate and a negative charge on the other plate is induced. The same capacitor will have a voltage across its terminals, and this is the field-induced voltage.

How to Calculate Induced EMF given Linear Synchronous Speed?

Induced EMF given Linear Synchronous Speed calculator uses Induced EMF = Linear Synchronous Speed*Magnetic Flux Density*Length of Conductor to calculate the Induced EMF, Induced EMF given Linear Synchronous Speed formula is is maximum at the start and varies according to the value of slip under running condition. Induced EMF is denoted by E_i symbol.

How to calculate Induced EMF given Linear Synchronous Speed using this online calculator? To use this online calculator for Induced EMF given Linear Synchronous Speed, enter Linear Synchronous Speed (V_s), Magnetic Flux Density (B) & Length of Conductor (l) and hit the calculate button. Here is how the Induced EMF given Linear Synchronous Speed calculation can be explained with given input values -> 4.8654 = 135*0.68*0.053.

FAQ

What is Induced EMF given Linear Synchronous Speed?

Induced EMF given Linear Synchronous Speed formula is is maximum at the start and varies according to the value of slip under running condition and is represented as E_i = V_s*B*l or Induced EMF = Linear Synchronous Speed*Magnetic Flux Density*Length of Conductor. Linear Synchronous Speed is the synchronous speed of the linear synchronous machine, Magnetic Flux Density is defined as the number of lines of force passing through a unit area of material & Length of Conductor is the net length of conductor present in the magnetic field.

How to calculate Induced EMF given Linear Synchronous Speed?

Induced EMF given Linear Synchronous Speed formula is is maximum at the start and varies according to the value of slip under running condition is calculated using Induced EMF = Linear Synchronous Speed*Magnetic Flux Density*Length of Conductor. To calculate Induced EMF given Linear Synchronous Speed, you need Linear Synchronous Speed (V_s), Magnetic Flux Density (B) & Length of Conductor (l). With our tool, you need to enter the respective value for Linear Synchronous Speed, Magnetic Flux Density & Length of Conductor 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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