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Force is defined as the attraction or repulsion that arises between particles because of the motion. Check FAQs
F=Bilsin(θ)
F - Force?B - Magnetic Flux Density?i - Electric Current?l - Length of Conductor?θ - Angle between Vectors?

Forces on Current Carrying Wires Example

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With units
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Here is how the Forces on Current Carrying Wires equation looks like with Values.

Here is how the Forces on Current Carrying Wires equation looks like with Units.

Here is how the Forces on Current Carrying Wires equation looks like.

0.1561Edit=0.2Edit2.89Edit270Editsin(90Edit)
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HomeIcon Home » Category Engineering » Category Electrical » Category Electrical Circuit » fx Forces on Current Carrying Wires

Forces on Current Carrying Wires Solution

Follow our step by step solution on how to calculate Forces on Current Carrying Wires?

FIRST Step Consider the formula
F=Bilsin(θ)
Next Step Substitute values of Variables
F=0.2T2.89A270mmsin(90°)
Next Step Convert Units
F=0.2T2.89A0.27msin(1.5708rad)
Next Step Prepare to Evaluate
F=0.22.890.27sin(1.5708)
Next Step Evaluate
F=0.15606N
LAST Step Rounding Answer
F=0.1561N

Forces on Current Carrying Wires Formula Elements

Variables
Functions
Force
Force is defined as the attraction or repulsion that arises between particles because of the motion.
Symbol: F
Measurement: ForceUnit: N
Note: Value should be greater than 0.
Formulas to find ForceOpen Variable
Magnetic Flux Density
Magnetic flux density is equal to the magnetic field strength times the absolute permeability of the region where the field exists. Magnetic flux density formula, B=μH.
Symbol: B
Measurement: Magnetic Flux DensityUnit: T
Note: Value should be greater than 0.
Formulas to find Magnetic Flux DensityOpen Variable
Electric Current
Electric Current is defined as the rate of flow of electrons in a conductor. The SI Unit of electric current is the Ampere.
Symbol: i
Measurement: Electric CurrentUnit: A
Note: Value can be positive or negative.
Formulas to find Electric CurrentOpen Variable
Length of Conductor
Length of Conductor is defined as the total length of the conductor carrying current through it.
Symbol: l
Measurement: LengthUnit: mm
Note: Value should be greater than 0.
Formulas to find Length of ConductorOpen Variable
Angle between Vectors
Angle between Vectors is defined as the angle made by the two vectors on a two phase plane with respect to the direction of movement of each other.
Symbol: θ
Measurement: AngleUnit: °
Note: Value can be positive or negative.
Formulas to find Angle between VectorsOpen Variable
sin
Sine is a trigonometric function that describes the ratio of the length of the opposite side of a right triangle to the length of the hypotenuse.
Syntax: sin(Angle)

Other Formulas to find Force

​Go Forces on Charges Moving in Magnetic Fields
F=quBsin(θ)

Other formulas in Electrical Specifications category

​Go Voltages Induced in Field Cutting Conductors
e=Blu
​Go Energy Stored in Magnetic Field
E=Bμ2
​Go Percent Voltage Regulation
%=(Vnl-ee)100
​Go Minimum Frequency to Avoid Saturation
f=Vm2πN2A

How to Evaluate Forces on Current Carrying Wires?

Forces on Current Carrying Wires evaluator uses Force = Magnetic Flux Density*Electric Current*Length of Conductor*sin(Angle between Vectors) to evaluate the Force, The Forces on Current Carrying Wires formula is defined as magnetic field exerts a force on a current-carrying wire in a direction given by the right hand rule 1 (the same direction as that on the individual moving charges). This force can easily be large enough to move the wire, since typical currents consist of very large numbers of moving charges. Force is denoted by F symbol.

How to evaluate Forces on Current Carrying Wires using this online evaluator? To use this online evaluator for Forces on Current Carrying Wires, enter Magnetic Flux Density (B), Electric Current (i), Length of Conductor (l) & Angle between Vectors (θ) and hit the calculate button.

FAQs on Forces on Current Carrying Wires

What is the formula to find Forces on Current Carrying Wires?
The formula of Forces on Current Carrying Wires is expressed as Force = Magnetic Flux Density*Electric Current*Length of Conductor*sin(Angle between Vectors). Here is an example- 0.15606 = 0.2*2.89*0.27*sin(1.5707963267946).
How to calculate Forces on Current Carrying Wires?
With Magnetic Flux Density (B), Electric Current (i), Length of Conductor (l) & Angle between Vectors (θ) we can find Forces on Current Carrying Wires using the formula - Force = Magnetic Flux Density*Electric Current*Length of Conductor*sin(Angle between Vectors). This formula also uses Sine (sin) function(s).
What are the other ways to Calculate Force?
Here are the different ways to Calculate Force-
  • Force=Electric Charge*Charge Velocity*Magnetic Flux Density*sin(Angle between Vectors)OpenImg
Can the Forces on Current Carrying Wires be negative?
No, the Forces on Current Carrying Wires, measured in Force cannot be negative.
Which unit is used to measure Forces on Current Carrying Wires?
Forces on Current Carrying Wires is usually measured using the Newton[N] for Force. Exanewton[N], Meganewton[N], Kilonewton[N] are the few other units in which Forces on Current Carrying Wires can be measured.
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