Maximum Core Flux Calculator

✖Maximum Flux Density is defined as the number of lines of force passing through a unit area of material.ⓘ Maximum Flux Density [B_max]			+10% -10%
✖Area of Core is defined as the space occupied by the core of a transformer in 2 dimensional space.ⓘ Area of Core [A_core]			+10% -10%

✖Maximum Core Flux is defined as the maximum amount of flux that is flowing through the coil of a transformer.ⓘ Maximum Core Flux [Φ_max]

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Formula

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Maximum Core Flux

Formula

`"Φ"_{"max"} = "B"_{"max"}*"A"_{"core"}`

Example

`"0.3mWb"="0.0012T"*"2500cm²"`

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Maximum Core Flux Solution

STEP 0: Pre-Calculation Summary

Formula Used

Maximum Core Flux = Maximum Flux Density*Area of Core
Φ_max = B_max*A_core
This formula uses 3 Variables

Variables Used

Maximum Core Flux - (Measured in Weber) - Maximum Core Flux is defined as the maximum amount of flux that is flowing through the coil of a transformer.
Maximum Flux Density - (Measured in Tesla) - Maximum Flux Density is defined as the number of lines of force passing through a unit area of material.
Area of Core - (Measured in Square Meter) - Area of Core is defined as the space occupied by the core of a transformer in 2 dimensional space.

STEP 1: Convert Input(s) to Base Unit

Maximum Flux Density: 0.0012 Tesla --> 0.0012 Tesla No Conversion Required
Area of Core: 2500 Square Centimeter --> 0.25 Square Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

Φ_max = B_max*A_core --> 0.0012*0.25

Evaluating ... ...

Φ_max = 0.0003

STEP 3: Convert Result to Output's Unit

0.0003 Weber -->0.3 Milliweber (Check conversion here)

FINAL ANSWER

0.3 Milliweber <-- Maximum Core Flux

(Calculation completed in 00.004 seconds)

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Credits

Created by Parminder Singh

Chandigarh University (CU), Punjab

Parminder Singh has created this Calculator and 100+ more calculators!

Verified by Pranav Simha R

BMS College of Engineering (BMSCE), Bangalore,India

Pranav Simha R has verified this Calculator and 1 more calculators!

< 19 Transformer Design Calculators

Eddy Current Loss

Go Eddy Current Loss = Eddy Current Coefficient*Maximum Flux Density^2*Supply Frequency^2*Lamination Thickness^2*Volume of Core

Hysteresis Loss

Go Hysteresis Loss = Hysteresis Constant*Supply Frequency*(Maximum Flux Density ^Steinmetz Coefficient)*Volume of Core

Area of Core given EMF Induced in Secondary Winding

Go Area of Core = EMF Induced in Secondary/(4.44*Supply Frequency*Number of Turns in Secondary*Maximum Flux Density)

Number of Turns in Secondary Winding

Go Number of Turns in Secondary = EMF Induced in Secondary/(4.44*Supply Frequency*Area of Core*Maximum Flux Density)

Number of Turns in Primary Winding

Go Number of Turns in Primary = EMF Induced in Primary/(4.44*Supply Frequency*Area of Core*Maximum Flux Density)

Area of Core given EMF Induced in Primary Winding

Go Area of Core = EMF Induced in Primary/(4.44*Supply Frequency*Number of Turns in Primary*Maximum Flux Density)

Percentage Regulation of Transformer

Go Percentage Regulation of Transformer = ((No Load Terminal Voltage-Full Load Terminal Voltage)/No Load Terminal Voltage)*100

Maximum Flux in Core using Secondary Winding

Go Maximum Core Flux = EMF Induced in Secondary/(4.44*Supply Frequency*Number of Turns in Secondary)

Maximum Flux in Core using Primary Winding

Go Maximum Core Flux = EMF Induced in Primary/(4.44*Supply Frequency*Number of Turns in Primary)

Secondary Winding Resistance given Impedance of Secondary Winding

Go Resistance of Secondary = sqrt(Impedance of Secondary^2-Secondary Leakage Reactance^2)

Primary Winding Resistance given Impedance of Primary Winding

Go Resistance of Primary = sqrt(Impedance of Primary^2-Primary Leakage Reactance^2)

EMF Induced in Primary Winding given Input Voltage

Go EMF Induced in Primary = Primary Voltage-Primary Current*Impedance of Primary

Utilisation Factor of Transformer Core

Go Utilisation Factor of Transformer Core = Net Cross Sectional Area/Total Cross Sectional Area

Stacking Factor of Transformer

Go Stacking Factor of Transformer = Net Cross Sectional Area/Gross Cross Sectional Area

Self-Induced EMF in Secondary Side

Go EMF Induced in Secondary = Secondary Leakage Reactance*Secondary Current

Self-Induced EMF in Primary Side

Go Self Induced EMF in Primary = Primary Leakage Reactance*Primary Current

Percentage All Day Efficiency of Transformer

Go All Day Efficiency = ((Output Energy)/(Input Energy))*100

Maximum Core Flux

Go Maximum Core Flux = Maximum Flux Density*Area of Core

Transformer Iron loss

Go Iron Losses = Eddy Current Loss+Hysteresis Loss

< 5 Magnetic Flux Calculators

Maximum Flux Density using Secondary Winding

Go Maximum Flux Density = EMF Induced in Secondary/(4.44*Area of Core*Supply Frequency*Number of Turns in Secondary)

Maximum Flux Density given Primary Winding

Go Maximum Flux Density = EMF Induced in Primary/(4.44*Area of Core*Supply Frequency*Number of Turns in Primary)

Maximum Flux in Core using Secondary Winding

Go Maximum Core Flux = EMF Induced in Secondary/(4.44*Supply Frequency*Number of Turns in Secondary)

Maximum Flux in Core using Primary Winding

Go Maximum Core Flux = EMF Induced in Primary/(4.44*Supply Frequency*Number of Turns in Primary)

Maximum Core Flux

Go Maximum Core Flux = Maximum Flux Density*Area of Core

Maximum Core Flux Formula

Maximum Core Flux = Maximum Flux Density*Area of Core
Φ_max = B_max*A_core

What is Maximum Core Flux?

The Maximum Core Flux is defined as the maximum amount of flux that is flowing through the coil of a transformer.

How to Calculate Maximum Core Flux?

Maximum Core Flux calculator uses Maximum Core Flux = Maximum Flux Density*Area of Core to calculate the Maximum Core Flux, The Maximum Core Flux is defined as the maximum amount of flux that is flowing through the coil of a transformer. Maximum Core Flux is denoted by Φ_max symbol.

How to calculate Maximum Core Flux using this online calculator? To use this online calculator for Maximum Core Flux, enter Maximum Flux Density (B_max) & Area of Core (A_core) and hit the calculate button. Here is how the Maximum Core Flux calculation can be explained with given input values -> 300 = 0.0012*0.25.

FAQ

What is Maximum Core Flux?

The Maximum Core Flux is defined as the maximum amount of flux that is flowing through the coil of a transformer and is represented as Φ_max = B_max*A_core or Maximum Core Flux = Maximum Flux Density*Area of Core. Maximum Flux Density is defined as the number of lines of force passing through a unit area of material & Area of Core is defined as the space occupied by the core of a transformer in 2 dimensional space.

How to calculate Maximum Core Flux?

The Maximum Core Flux is defined as the maximum amount of flux that is flowing through the coil of a transformer is calculated using Maximum Core Flux = Maximum Flux Density*Area of Core. To calculate Maximum Core Flux, you need Maximum Flux Density (B_max) & Area of Core (A_core). With our tool, you need to enter the respective value for Maximum Flux Density & Area of Core 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 Maximum Core Flux?

In this formula, Maximum Core Flux uses Maximum Flux Density & Area of Core. We can use 4 other way(s) to calculate the same, which is/are as follows -

Maximum Core Flux = EMF Induced in Primary/(4.44*Supply Frequency*Number of Turns in Primary)
Maximum Core Flux = EMF Induced in Secondary/(4.44*Supply Frequency*Number of Turns in Secondary)
Maximum Core Flux = EMF Induced in Primary/(4.44*Supply Frequency*Number of Turns in Primary)
Maximum Core Flux = EMF Induced in Secondary/(4.44*Supply Frequency*Number of Turns in Secondary)

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