Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given Calculator

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✖The number of Turns in Secondary winding is the number of turns secondary winding has.ⓘ Number of Turns in Secondary winding [N2]			+10% -10%
✖The number of Turns in Primary winding is the number of turns primary winding has.ⓘ Number of Turns in Primary winding [N1]			+10% -10%

✖the voltage transformation ratio of the transformer is used to find the relation between primary voltage and secondary voltage.ⓘ Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given [K]

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Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given

Urvi Rathod

Vishwakarma Government Engineering College (VGEC), Ahmedabad

Urvi Rathod has created this Calculator and 500+ more calculators!

Anirudh Singh

National Institute of Technology (NIT), Jamshedpur

Anirudh Singh has verified this Calculator and 100+ more calculators!

< 11 Other formulas that you can solve using the same Inputs

Frequency When EMF Induced In Secondary Winding is Given

frequency=EMF Induced In The Secondary Winding/(4.44*Number of Turns in Secondary winding*Area*Maximum flux density) GO

Maximum Flux Density When Secondary Winding Is Given

Maximum flux density=EMF Induced In The Secondary Winding/(4.44*frequency*Number of Turns in Secondary winding*Area) GO

Area Of Core When EMF Induced In Secondary Winding Is Given

Area=EMF Induced In The Secondary Winding/(4.44*frequency*Number of Turns in Primary winding*Maximum flux density) GO

EMF Induced In Secondary Winding

EMF Induced In The Secondary Winding=4.44*Number of Turns in Secondary winding*frequency*Area*Maximum flux density GO

Area Of Core When EMF Induced In Primary Winding Is Given

Area=EMF Induced In The Primary Winding/(4.44*frequency*Number of Turns in Primary winding*Maximum flux density) GO

Frequency When EMF Induced In Primary Winding is Given

frequency=EMF Induced In The Primary Winding/(4.44*Number of Turns in Primary winding*Area*Maximum flux density) GO

Maximum Flux Density When Primary Winding Is Given

Maximum flux density=EMF Induced In The Primary Winding/(4.44*Area*frequency*Number of Turns in Primary winding) GO

EMF Induced In Primary Winding

EMF Induced In The Primary Winding=4.44*Number of Turns in Primary winding*frequency*Area*Maximum flux density GO

Maximum Flux In Core When Secondary Winding Is Given

Magnetic Flux=EMF Induced In The Secondary Winding/(4.44*frequency*Number of Turns in Secondary winding) GO

Number Of Turns In The Primary Winding When Voltage Transformation Ratio Is Given

Number of Turns in Primary winding=Number of Turns in Secondary winding/Voltage Transformation Ratio GO

Maximum Flux In Core When Primary Winding Is Given

Magnetic Flux=EMF Induced In The Primary Winding/(4.44*frequency*Number of Turns in Primary winding) GO

< 11 Other formulas that calculate the same Output

Voltage Transformation Ratio When Equivalent Resistance From Primary Side Is Given

Voltage Transformation Ratio=sqrt(Resistance of Secondary winding/(Equivalent resistance of transformer from primary-Resistance of primary winding)) GO

Voltage Transformation Ratio When Secondary Leakage Resistance Is Given

Voltage Transformation Ratio=sqrt(Resistance of Secondary winding/(Equivalent resistance of transformer from primary-Resistance of primary winding)) GO

Voltage Transformation Ratio When Equivalent Resistance From Secondary Side Is Given

Voltage Transformation Ratio=sqrt(Resistance of primary winding/(Equivalent resistance from Secondary-Resistance of Secondary winding)) GO

Voltage Transformation Ratio When Primary Leakage Resistance Is Given

Voltage Transformation Ratio=sqrt(Resistance of primary winding/(Equivalent resistance from Secondary-Resistance of Secondary winding)) GO

Voltage Transformation Ratio When Equivalent Reactance From Secondary Side Is Given

Voltage Transformation Ratio=sqrt((Equivalent reactance from secondary-Secondary leakage Reactance)/Primary leakage Reactance) GO

Voltage Transformation Ratio When Equivalent Reactance From Primary Side Is Given

Voltage Transformation Ratio=sqrt(Secondary leakage Reactance/(Equivalent reactance from primary-Primary leakage Reactance)) GO

Voltage Transformation Ratio When Primary And Secondary Induced Voltage Is Given

Voltage Transformation Ratio=EMF Induced In The Secondary Winding/EMF Induced In The Primary Winding GO

Voltage Transformation Ratio When Secondary Leakage Reactance Is Given

Voltage Transformation Ratio=sqrt(Secondary leakage Reactance/Reactance of Secondary in primary) GO

Voltage Transformation Ratio When Primary Leakage Reactance Is Given

Voltage Transformation Ratio=sqrt(Reactance of Primary in Secondary/Primary leakage Reactance) GO

Voltage Transformation Ratio When Primary And Secondary Current Is Given

Voltage Transformation Ratio=Primary Current /Secondary Current GO

Voltage Transformation Ratio When Primary And Secondary Voltage Is Given

Voltage Transformation Ratio=Voltage2/voltage1 GO

Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given Formula

Voltage Transformation Ratio=Number of Turns in Secondary winding/Number of Turns in Primary winding
K=N2/N1

More formulas

Voltage Transformation Ratio When Primary And Secondary Voltage Is Given GO

Voltage Transformation Ratio When Primary And Secondary Current Is Given GO

Voltage Transformation Ratio When Primary And Secondary Induced Voltage Is Given GO

Voltage Transformation Ratio When Secondary Leakage Reactance Is Given GO

Voltage Transformation Ratio When Primary Leakage Reactance Is Given GO

Voltage Transformation Ratio When Primary Leakage Resistance Is Given GO

Voltage Transformation Ratio When Secondary Leakage Resistance Is Given GO

Voltage Transformation Ratio When Equivalent Resistance From Primary Side Is Given GO

Voltage Transformation Ratio When Equivalent Resistance From Secondary Side Is Given GO

Voltage Transformation Ratio When Equivalent Reactance From Secondary Side Is Given GO

Voltage Transformation Ratio When Equivalent Reactance From Primary Side Is Given GO

Is the ratio between turns and voltage the same in the transformer?

Transformers are all about “ratios”. The ratio of the primary to the secondary, the ratio of the input to the output, and the turns ratio of any given transformer will be the same as its voltage ratio. the ratio between the number of turns changes the resulting voltages must also change by the same ratio.

How to Calculate Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given?

Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given calculator uses Voltage Transformation Ratio=Number of Turns in Secondary winding/Number of Turns in Primary winding to calculate the Voltage Transformation Ratio, The Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given formula is defined as the ratio of the EMF in the secondary coil to that in the primary coil. Voltage Transformation Ratio and is denoted by K symbol.

How to calculate Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given using this online calculator? To use this online calculator for Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given, enter Number of Turns in Secondary winding (N2) and Number of Turns in Primary winding (N1) and hit the calculate button. Here is how the Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given calculation can be explained with given input values -> 2.5 = 50/20.

FAQ

What is Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given?

The Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given formula is defined as the ratio of the EMF in the secondary coil to that in the primary coil and is represented as K=N2/N1 or Voltage Transformation Ratio=Number of Turns in Secondary winding/Number of Turns in Primary winding. The number of Turns in Secondary winding is the number of turns secondary winding has and The number of Turns in Primary winding is the number of turns primary winding has.

How to calculate Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given?

The Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given formula is defined as the ratio of the EMF in the secondary coil to that in the primary coil is calculated using Voltage Transformation Ratio=Number of Turns in Secondary winding/Number of Turns in Primary winding. To calculate Voltage Transformation Ratio When Primary And Secondary Number Of Turns Is Given, you need Number of Turns in Secondary winding (N2) and Number of Turns in Primary winding (N1). With our tool, you need to enter the respective value for Number of Turns in Secondary winding and Number of Turns in Primary winding 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 Voltage Transformation Ratio?

In this formula, Voltage Transformation Ratio uses Number of Turns in Secondary winding and Number of Turns in Primary winding. We can use 11 other way(s) to calculate the same, which is/are as follows -

Voltage Transformation Ratio=Voltage2/voltage1
Voltage Transformation Ratio=Primary Current /Secondary Current
Voltage Transformation Ratio=EMF Induced In The Secondary Winding/EMF Induced In The Primary Winding
Voltage Transformation Ratio=sqrt(Secondary leakage Reactance/Reactance of Secondary in primary)
Voltage Transformation Ratio=sqrt(Reactance of Primary in Secondary/Primary leakage Reactance)
Voltage Transformation Ratio=sqrt(Resistance of primary winding/(Equivalent resistance from Secondary-Resistance of Secondary winding))
Voltage Transformation Ratio=sqrt(Resistance of Secondary winding/(Equivalent resistance of transformer from primary-Resistance of primary winding))
Voltage Transformation Ratio=sqrt(Resistance of Secondary winding/(Equivalent resistance of transformer from primary-Resistance of primary winding))
Voltage Transformation Ratio=sqrt(Resistance of primary winding/(Equivalent resistance from Secondary-Resistance of Secondary winding))
Voltage Transformation Ratio=sqrt((Equivalent reactance from secondary-Secondary leakage Reactance)/Primary leakage Reactance)
Voltage Transformation Ratio=sqrt(Secondary leakage Reactance/(Equivalent reactance from primary-Primary leakage Reactance))

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