Voltages Induced in Field Cutting Conductors Solution

STEP 0: Pre-Calculation Summary
Formula Used
Voltage = Magnetic Flux Density*Length of Conductor*Charge Velocity
e = B*l*u
This formula uses 4 Variables
Variables Used
Voltage - (Measured in Volt) - Voltage can be defined as electric potential along a wire when an electric current of one ampere dissipates one watt of power.
Magnetic Flux Density - (Measured in Tesla) - Magnetic Flux Density is amount of magnetic flux through unit area taken perpendicular to direction of magnetic flux.
Length of Conductor - (Measured in Meter) - Length of Conductor is defined as the total length of the conductor carrying current through it.
Charge Velocity - (Measured in Meter per Second) - Charge Velocity is defined as the speed with which charge drifts in a conductor.
STEP 1: Convert Input(s) to Base Unit
Magnetic Flux Density: 0.019 Tesla --> 0.019 Tesla No Conversion Required
Length of Conductor: 2750 Millimeter --> 2.75 Meter (Check conversion here)
Charge Velocity: 4250000 Meter per Second --> 4250000 Meter per Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
e = B*l*u --> 0.019*2.75*4250000
Evaluating ... ...
e = 222062.5
STEP 3: Convert Result to Output's Unit
222062.5 Volt --> No Conversion Required
222062.5 Volt <-- Voltage
(Calculation completed in 00.000 seconds)
You are here -
Home »

Credits

Created by Parminder Singh
Chandigarh University (CU), Punjab
Parminder Singh has created this Calculator and 50+ more calculators!
Verified by Aman Dhussawat
GURU TEGH BAHADUR INSTITUTE OF TECHNOLOGY (GTBIT), NEW DELHI
Aman Dhussawat has verified this Calculator and 9 more calculators!

< 23 Basics of Magnetism Calculators

Mutual Inductance
Mutual Inductance = [Permeability-vacuum]*Relative Permeability*Area of Coil*Number of Conductors*Secondary Turns of Coil/Mean Length
Magnetic Potential
Magnetic Potential = (Magnetic Moment)/(4*pi*[Permeability-vacuum]*Relative Permeability*Pole Distance)
Flux Density in Toroidal Core
Magnetic Flux Density = (Relative Permeability*Secondary Turns of Coil*Current)/(pi*Inner Diameter)
Forces on Charges Moving in Magnetic Fields
Force = [Charge-e]*Charge Velocity*Magnetic Flux Density*(sin(Angle between Vectors))
Forces on Current Carrying Wires
Force = Magnetic Flux Density*Current*Length of Conductor*sin(Angle between Vectors)
Average Hysteresis Power Loss
Hysteresis Loss = Hysteresis Constant*Frequency*(Magnetic Flux Density)^Steinmetz Coefficient
Minimum Frequency to Avoid Saturation
Frequency = Peak Voltage/(2*pi*Secondary Turns of Coil*Area of Coil)
Reluctance
Reluctance = Mean Length/(Magnetic Permeability of a Medium*Area of Coil)
Voltages Induced in Field Cutting Conductors
Voltage = Magnetic Flux Density*Length of Conductor*Charge Velocity
Percent Voltage Regulation
Percentage Regulation = ((No Load Voltage-Voltage)/Voltage)*100
Self Inductance
Self Inductance = (Number of Conductors*Magnetic Flux)/Current
Magnetic Flux Density using Magnetic Field Intensity
Magnetic Flux Density = Magnetic Permeability of a Medium*Magnetic Field Intensity
Magnetic Susceptibility
Magnetic Susceptibility = Intensity of Magnetization/Magnetic Field Intensity
Energy Stored in Magnetic Field
Energy = Magnetic Flux Density/(Magnetic Permeability of a Medium^2)
Intensity of Magnetization
Intensity of Magnetization = Magnetic Moment/Volume
Magnetic Flux using Flux Density
Magnetic Flux = Magnetic Flux Density*Area of Coil
Magnetic Flux Density
Magnetic Flux Density = Magnetic Flux/Area of Coil
Magnetic Field Strength
Magnetic Field Strength = Force/Magnetic Moment
Magnetic Flux in Core
Magnetic Flux = Magnetomotive Force/Reluctance
Area of Ring
Area of Coil = (pi*Inner Diameter^2)/4
Mean Diameter
Mean Diameter = Mean Length/pi
Mean Length
Mean Length = pi*Mean Diameter
Permeance
Magnetic Permeance = 1/Reluctance

Voltages Induced in Field Cutting Conductors Formula

Voltage = Magnetic Flux Density*Length of Conductor*Charge Velocity
e = B*l*u

What is Faraday’s Law of Electromagnetic Induction?

Electromagnetic Induction was first discovered way back in the 1830’s by Michael Faraday. Faraday noticed that when he moved a permanent magnet in and out of a coil or a single loop of wire it induced an ElectroMotive Force or emf, in other words a Voltage, and therefore a current was produced.

How to Calculate Voltages Induced in Field Cutting Conductors?

Voltages Induced in Field Cutting Conductors calculator uses Voltage = Magnetic Flux Density*Length of Conductor*Charge Velocity to calculate the Voltage, The Voltages Induced in Field Cutting Conductors formula is defined as when an electric current flowing through a single wire will produce a magnetic field around it. If the wire is wound into a coil, the magnetic field is greatly intensified producing a static magnetic field around itself forming the shape of a bar magnet giving a distinct North and South pole. Voltage is denoted by e symbol.

How to calculate Voltages Induced in Field Cutting Conductors using this online calculator? To use this online calculator for Voltages Induced in Field Cutting Conductors, enter Magnetic Flux Density (B), Length of Conductor (l) & Charge Velocity (u) and hit the calculate button. Here is how the Voltages Induced in Field Cutting Conductors calculation can be explained with given input values -> 222062.5 = 0.019*2.75*4250000.

FAQ

What is Voltages Induced in Field Cutting Conductors?
The Voltages Induced in Field Cutting Conductors formula is defined as when an electric current flowing through a single wire will produce a magnetic field around it. If the wire is wound into a coil, the magnetic field is greatly intensified producing a static magnetic field around itself forming the shape of a bar magnet giving a distinct North and South pole and is represented as e = B*l*u or Voltage = Magnetic Flux Density*Length of Conductor*Charge Velocity. Magnetic Flux Density is amount of magnetic flux through unit area taken perpendicular to direction of magnetic flux, Length of Conductor is defined as the total length of the conductor carrying current through it & Charge Velocity is defined as the speed with which charge drifts in a conductor.
How to calculate Voltages Induced in Field Cutting Conductors?
The Voltages Induced in Field Cutting Conductors formula is defined as when an electric current flowing through a single wire will produce a magnetic field around it. If the wire is wound into a coil, the magnetic field is greatly intensified producing a static magnetic field around itself forming the shape of a bar magnet giving a distinct North and South pole is calculated using Voltage = Magnetic Flux Density*Length of Conductor*Charge Velocity. To calculate Voltages Induced in Field Cutting Conductors, you need Magnetic Flux Density (B), Length of Conductor (l) & Charge Velocity (u). With our tool, you need to enter the respective value for Magnetic Flux Density, Length of Conductor & Charge Velocity and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
Let Others Know