Secondary Voltage given Voltage Transformation Ratio Solution

STEP 0: Pre-Calculation Summary
Formula Used
Secondary Voltage = Primary Voltage*Transformation Ratio
V2 = V1*K
This formula uses 3 Variables
Variables Used
Secondary Voltage - (Measured in Volt) - Secondary Voltage is defined as the voltage on the secondary side of a transformer or the side at which load is connected.
Primary Voltage - (Measured in Volt) - Primary Voltage means the level of voltage at facilities at which electric power is taken or delivered, generally at a level between 12 kV and 33 kV, but always between 2 kV and 50 kV.
Transformation Ratio - The Transformation Ratio of the transformer is used to find the relation between primary voltage and secondary voltage.
STEP 1: Convert Input(s) to Base Unit
Primary Voltage: 240 Volt --> 240 Volt No Conversion Required
Transformation Ratio: 1.2 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
V2 = V1*K --> 240*1.2
Evaluating ... ...
V2 = 288
STEP 3: Convert Result to Output's Unit
288 Volt --> No Conversion Required
FINAL ANSWER
288 Volt <-- Secondary Voltage
(Calculation completed in 00.004 seconds)

Credits

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Vishwakarma Government Engineering College (VGEC), Ahmedabad
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National Institute of Technology (NIT), Jamshedpur
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12 Voltage & EMF Calculators

EMF Induced in Secondary Winding
Go EMF Induced in Secondary = 4.44*Number of Turns in Secondary*Supply Frequency*Area of Core*Maximum Flux Density
EMF Induced in Primary Winding
Go EMF Induced in Primary = 4.44*Number of Turns in Primary*Supply Frequency*Area of Core*Maximum Flux Density
Terminal Voltage during No Load
Go No Load Terminal Voltage = (Primary Voltage* Number of Turns in Secondary)/Number of Turns in Primary
Output Voltage given EMF Induced in Secondary Winding
Go Secondary Voltage = EMF Induced in Secondary-Secondary Current*Impedance of Secondary
EMF Induced in Primary Winding given Input Voltage
Go EMF Induced in Primary = Primary Voltage-Primary Current*Impedance of Primary
Input Voltage when EMF Induced in Primary Winding
Go Primary Voltage = EMF Induced in Primary+Primary Current*Impedance of Primary
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
EMF Induced in Secondary Winding given Voltage Transformation Ratio
Go EMF Induced in Secondary = EMF Induced in Primary*Transformation Ratio
EMF Induced in Primary Winding given Voltage Transformation Ratio
Go EMF Induced in Primary = EMF Induced in Secondary/Transformation Ratio
Secondary Voltage given Voltage Transformation Ratio
Go Secondary Voltage = Primary Voltage*Transformation Ratio
Primary Voltage given Voltage Transformation Ratio
Go Primary Voltage = Secondary Voltage/Transformation Ratio

25 Transformer Circuit Calculators

EMF Induced in Secondary Winding
Go EMF Induced in Secondary = 4.44*Number of Turns in Secondary*Supply Frequency*Area of Core*Maximum Flux Density
EMF Induced in Primary Winding
Go EMF Induced in Primary = 4.44*Number of Turns in Primary*Supply Frequency*Area of Core*Maximum Flux Density
Equivalent Impedance of Transformer from Secondary Side
Go Equivalent Impedance from Secondary = sqrt(Equivalent Resistance from Secondary^2+Equivalent Reactance from Secondary^2)
Equivalent Impedance of Transformer from Primary Side
Go Equivalent Impedance from Primary = sqrt(Equivalent Resistance from Primary^2+Equivalent Reactance from Primary^2)
Equivalent Resistance from Secondary Side
Go Equivalent Resistance from Secondary = Resistance of Secondary+Resistance of Primary*Transformation Ratio^2
Equivalent Resistance from Primary Side
Go Equivalent Resistance from Primary = Resistance of Primary+Resistance of Secondary/Transformation Ratio^2
P.U. Primary Resistance Drop
Go P U Primary Resistance drop = (Primary Current*Equivalent Resistance from Primary)/EMF Induced in Primary
Terminal Voltage during No Load
Go No Load Terminal Voltage = (Primary Voltage* Number of Turns in Secondary)/Number of Turns in Primary
Transformation Ratio given Secondary Leakage Reactance
Go Transformation Ratio = sqrt(Secondary Leakage Reactance/Reactance of Secondary in Primary)
Transformation Ratio given Primary Leakage Reactance
Go Transformation Ratio = sqrt(Reactance of Primary in Secondary/Primary Leakage Reactance)
Equivalent Reactance of Transformer from Secondary Side
Go Equivalent Reactance from Secondary = Secondary Leakage Reactance+Reactance of Primary in Secondary
Equivalent Reactance of Transformer from Primary Side
Go Equivalent Reactance from Primary = Primary Leakage Reactance+Reactance of Secondary in Primary
Reactance of Secondary Winding in Primary
Go Reactance of Secondary in Primary = Secondary Leakage Reactance/(Transformation Ratio^2)
Primary Leakage Reactance
Go Primary Leakage Reactance = Reactance of Primary in Secondary/(Transformation Ratio^2)
Reactance of Primary Winding in Secondary
Go Reactance of Primary in Secondary = Primary Leakage Reactance*Transformation Ratio^2
Resistance of Secondary Winding in Primary
Go Resistance of Secondary in Primary = Resistance of Secondary/Transformation Ratio^2
Secondary Winding Resistance
Go Resistance of Secondary = Resistance of Secondary in Primary*Transformation Ratio^2
Primary Winding Resistance
Go Resistance of Primary = Resistance of Primary in Secondary/(Transformation Ratio^2)
Resistance of Primary Winding in Secondary
Go Resistance of Primary in Secondary = Resistance of Primary*Transformation Ratio^2
Transformation Ratio given Primary and Secondary Number of Turns
Go Transformation Ratio = Number of Turns in Secondary/Number of Turns in Primary
Secondary Leakage Reactance
Go Secondary Leakage Reactance = Self Induced EMF in Secondary/Secondary Current
Transformation Ratio given Primary and Secondary Current
Go Transformation Ratio = Primary Current/Secondary Current
Transformation Ratio given Primary and Secondary Voltage
Go Transformation Ratio = Secondary Voltage/Primary Voltage
Secondary Voltage given Voltage Transformation Ratio
Go Secondary Voltage = Primary Voltage*Transformation Ratio
Primary Voltage given Voltage Transformation Ratio
Go Primary Voltage = Secondary Voltage/Transformation Ratio

Secondary Voltage given Voltage Transformation Ratio Formula

Secondary Voltage = Primary Voltage*Transformation Ratio
V2 = V1*K

What is transformer transformation ratio?

It is actually defined as a transformer. Transformation Ratio (K) is defined as the ratio of the EMF in the secondary coil to that in the primary coil. Due to the resistance in the winding and some leakage flux, there is some loss in voltage. This is called Voltage Drop.

How to Calculate Secondary Voltage given Voltage Transformation Ratio?

Secondary Voltage given Voltage Transformation Ratio calculator uses Secondary Voltage = Primary Voltage*Transformation Ratio to calculate the Secondary Voltage, The Secondary Voltage given Voltage Transformation Ratio formula is defined as the coil winding supplying the output voltage. The output voltage of a transformer varies some with varying load resistances, even with a constant voltage input. Secondary Voltage is denoted by V2 symbol.

How to calculate Secondary Voltage given Voltage Transformation Ratio using this online calculator? To use this online calculator for Secondary Voltage given Voltage Transformation Ratio, enter Primary Voltage (V1) & Transformation Ratio (K) and hit the calculate button. Here is how the Secondary Voltage given Voltage Transformation Ratio calculation can be explained with given input values -> 288 = 240*1.2.

FAQ

What is Secondary Voltage given Voltage Transformation Ratio?
The Secondary Voltage given Voltage Transformation Ratio formula is defined as the coil winding supplying the output voltage. The output voltage of a transformer varies some with varying load resistances, even with a constant voltage input and is represented as V2 = V1*K or Secondary Voltage = Primary Voltage*Transformation Ratio. Primary Voltage means the level of voltage at facilities at which electric power is taken or delivered, generally at a level between 12 kV and 33 kV, but always between 2 kV and 50 kV & The Transformation Ratio of the transformer is used to find the relation between primary voltage and secondary voltage.
How to calculate Secondary Voltage given Voltage Transformation Ratio?
The Secondary Voltage given Voltage Transformation Ratio formula is defined as the coil winding supplying the output voltage. The output voltage of a transformer varies some with varying load resistances, even with a constant voltage input is calculated using Secondary Voltage = Primary Voltage*Transformation Ratio. To calculate Secondary Voltage given Voltage Transformation Ratio, you need Primary Voltage (V1) & Transformation Ratio (K). With our tool, you need to enter the respective value for Primary Voltage & Transformation Ratio 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 Secondary Voltage?
In this formula, Secondary Voltage uses Primary Voltage & Transformation Ratio. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Secondary Voltage = EMF Induced in Secondary-Secondary Current*Impedance of Secondary
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