6 Other formulas that you can solve using the same Inputs

Magnetic Field Due to a Straight Conductor
Magnetic Field=([Permeability-vacuum]*Electric Current/4*pi*Perpendicular Distance)*(cos(Theta 1)-cos(Theta 2)) GO
Output Voltage When EMF Induced In Secondary Winding Is Given
Voltage2=EMF Induced In The Secondary Winding-(Electric Current in Conductor 2*Impedance of Secondary winding) GO
Magnetic Field on the Axis of a Ring
Magnetic Field=([Permeability-vacuum]*Electric Current*Radius^2)/(2*(Radius^2+Perpendicular Distance^2)^(3/2)) GO
Input Voltage When EMF Induced In Primary Winding Is Given
voltage1=EMF Induced In The Primary Winding+(Electric Current in Conductor 1*Impedance of primary winding) GO
Magnetic Field Due to an Infinite Straight Wire
Magnetic Field=([Permeability-vacuum]*Electric Current)/(2*pi*Perpendicular Distance) GO
Chord length when radius and perpendicular distance are given
Chord Length=sqrt(Radius^2-Perpendicular Distance^2)*2 GO

Force Between Parallel Wires Formula

magnetic force per unit length=([Permeability-vacuum]*Electric Current in Conductor 1*Electric Current in Conductor 2)/(2*pi*Perpendicular Distance)
More formulas
Magnetic Field Due to a Straight Conductor GO
Magnetic Field Due to an Infinite Straight Wire GO
Magnetic Field on the Axis of a Ring GO
Field at the Center of an Arc GO
Field Inside a Solenoid GO
field at the center of the ring GO
Field of a Bar Magnet at axial position GO
Field of a Bar Magnet at equatorial position GO
Angle of Dip GO
Magnetic Field for a Tangent Galvanometer GO
Electric Current for a Tangent Galvanometer GO
Current for a Moving Coil Galvanometer GO
Time Period of Magnetometer GO
Magnetic Permeability GO

How is force arised due to magnetic field ?

Magnetic fields can exert a force on electric charge only if it is moving, just as a moving charge produces a magnetic field. This force increases with both an increase in charge and magnetic field strength. Moreover, the force is greater when charges have higher velocities.

How to Calculate Force Between Parallel Wires?

Force Between Parallel Wires calculator uses magnetic force per unit length=([Permeability-vacuum]*Electric Current in Conductor 1*Electric Current in Conductor 2)/(2*pi*Perpendicular Distance) to calculate the magnetic force per unit length, The Force Between Parallel Wires formula is defined as the force of attraction or repulsion between the two current carrying wires. SI unit is Newton/meter. magnetic force per unit length and is denoted by F/l symbol.

How to calculate Force Between Parallel Wires using this online calculator? To use this online calculator for Force Between Parallel Wires, enter Perpendicular Distance (d), Electric Current in Conductor 1 (i1 and Electric Current in Conductor 2 (i2 and hit the calculate button. Here is how the Force Between Parallel Wires calculation can be explained with given input values -> 0 = ([Permeability-vacuum]*(0)*(0))/(2*pi*0.03).

FAQ

What is Force Between Parallel Wires?
The Force Between Parallel Wires formula is defined as the force of attraction or repulsion between the two current carrying wires. SI unit is Newton/meter and is represented as F/l=([Permeability-vacuum]*i12 or magnetic force per unit length=([Permeability-vacuum]*Electric Current in Conductor 1*Electric Current in Conductor 2)/(2*pi*Perpendicular Distance). The perpendicular distance between two objects is the distance from one to the other, measured along a line that is perpendicular to one or both, Electric Current in Conductor 1 is the magnitude of current flowing through conductor 1 and Electric Current in Conductor 2 is the magnitutde of current flowing through conductor 2.
How to calculate Force Between Parallel Wires?
The Force Between Parallel Wires formula is defined as the force of attraction or repulsion between the two current carrying wires. SI unit is Newton/meter is calculated using magnetic force per unit length=([Permeability-vacuum]*Electric Current in Conductor 1*Electric Current in Conductor 2)/(2*pi*Perpendicular Distance). To calculate Force Between Parallel Wires, you need Perpendicular Distance (d), Electric Current in Conductor 1 (i1 and Electric Current in Conductor 2 (i2. With our tool, you need to enter the respective value for Perpendicular Distance, Electric Current in Conductor 1 and Electric Current in Conductor 2 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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