Transformer Voltage Multiplication Factor Calculation

AI Thread Summary
To calculate the voltage multiplication factor of a transformer with an output voltage of 13 V and an input current of 34 A, the ideal transformer equation is used: V_out/V_in = n. The discussion highlights that the 74 W mentioned is not the nominal power but rather the actual power delivered to a load, which can vary based on the load connected. It emphasizes that while input power equals output power in an ideal transformer, real-life transformers experience losses due to factors like winding resistance and core losses. Therefore, without additional data on input voltage or load characteristics, determining the exact multiplication factor is challenging. Understanding these principles is crucial for accurate transformer calculations.
orionj
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The output voltage of a 74 W transformer is 13 V, and the input current is 34 A.

By what factor is the voltage multiplied?

V_{s}
------=?
V_{P}

Honestly I am not sure exactly where to start in solving this problem.
 
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Any ideas?
 
The power that goes through transformer depends on the loading!

For instance if you plug your mobile phone supply to the power socket and not plug the mobile phone to it the power that goes through transformer is nearly 0!

And then if you connect your mobile phone to it the charging power goes through transformer to your phone. So the transformer power is not 0!

Generally every transformer has a parameter - nominal power which should not be exceeded unless you want to burn the device. If you say '74 W transformer' for electrical engineer it means that the transformer has NOMINAL POWER 74W.

But in this case the given power is not nominal power of the transformer (it is a little bit confusing). If so we would have too few data to solve the problem.

74W (i think) is the power that actually goes through transformer to some (unknown) loading.

The equations you should use are:

\frac{V_{out}}{V_{in}} = n (ideal transformer equation)

P_{in} = V_{in}I_{in} (input power)

P_{in} = V_{out}I_{out} (output power)

And of course input power is equal to output power (there is no loss in transformer)
 
a-lbi's input/output power are the equations you will have to use in this case. As Pinestone remarks there are losses in a real transformer but if they are the only values you have it must be an ideal transformer. You don't have things like a magnetising reactance, core loss resistance, winding resistance etc. to model the equivalent circuit for a non-ideal transformer.
 

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