Tapped Transformer With a Capacitor

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Discussion Overview

The discussion revolves around analyzing a tapped transformer circuit with a capacitor, focusing on determining load voltages, currents, and the resistance reflected into the primary. Participants explore the implications of treating loads in parallel versus series, and the calculations involved in determining reflected resistance and impedance.

Discussion Character

  • Technical explanation
  • Mathematical reasoning
  • Debate/contested

Main Points Raised

  • Some participants suggest that the transformer can be treated as having two independent secondary windings, implying that the loads are in parallel.
  • One participant questions why the voltage across the two branches would differ, given the proposed parallel configuration.
  • Another participant provides a calculation for reflected resistance, but expresses confusion about the results and the reasoning behind the given answer of 34.5 Ohms.
  • Some participants emphasize the importance of using basic physics principles, such as Faraday's and Ampere's laws, to approach the problem.
  • There is a discussion about whether to include the capacitor's reactance in the reflected resistance calculation, with some arguing it should not be included.
  • One participant expresses uncertainty about how to calculate the flux due to a lack of information regarding area or magnetic field.
  • Another participant clarifies that the primary current may not be in phase with the primary voltage, introducing a phase consideration into the discussion.

Areas of Agreement / Disagreement

Participants exhibit disagreement regarding the treatment of the loads (parallel versus series) and the inclusion of the capacitor in resistance calculations. There is no consensus on the correct approach or final answers, as various interpretations and calculations are presented.

Contextual Notes

Participants note limitations in the information provided, such as missing details about the magnetic field and area necessary for calculating flux. There are also unresolved questions about the turns assigned to each winding and how to properly calculate reflected resistance versus impedance.

Who May Find This Useful

This discussion may be useful for individuals interested in transformer theory, electrical engineering concepts, and the application of fundamental physics laws in circuit analysis.

Ahmed Bushra
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The question is the following:

a) Determine all load voltages and currents
b) Determine the resistance reflected into the primary.

Answer a) R(l): 35V, 2.91A, X(cl): 15V, 1.5 A

The answer to part (b) is apparently 34.5 Ohms.

How did they arrive at these answers?

I am not sure whether both loads should be treated as parallel or in series. Since the polarity in the bottom half should be opposite, and hence the currents should be in the same direction (?).

How should the impedance/resistance in the secondary circuit be calculated?

I had ignored the impedance of the capacitor and arrived at a reflected resistance of 35.26 Ohms.

R(primary)=(1/n2) R(secondary)
 
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You should be able to treat this as though the transformer has two independent secondary windings. This means the secondaries' loads are "in parallel".
 
I see,

Well, in that case why would the voltage across one brach be different than the voltage across the other? (35 V and 10 V respectively)

Also, the resistance is:
12*10/10+12= 5.45 Ohms,

Primary Resistance = (1/n)2 ( Secondary Resistance)
n being the turns ration: 700/1200

Primary Resistance = 2.938 X 5.45 = 16.02

Why does the answer say 34.5 Ohms? Have I gone wrong somewhere?
 
What do you mean by "branch"?

Your calculation for reflected resistance in your first post looked right.

What is the "10" in your resistance calculation? You need some brackets ( ) in your expression, too.

How many turns are you going to assign to each of the independent windings?
 
You might want to approach this problem from a basic-physics viewpoint: all you need is Faraday's and Ampere's laws.
1. what is the flux (easy)?
2. so what are the output voltages? (easy too)
3. and the currents thru C and R? (easy too, bit of algebra required)
4. finally, and more challenging: what is the primary current? this will include a phase other than 0.
 
NascentOxygen said:
What do you mean by "branch"?

Your calculation for reflected resistance in your first post looked right.

What is the "10" in your resistance calculation? You need some brackets ( ) in your expression, too.

How many turns are you going to assign to each of the independent windings?
By "branch" I mean each section of the parallel circuit. The first section being the one containing the resistor. The second section is containing the capacitor.

The "10" in the resistance calculation is the resistance of the capacitor. When I treat the secondary load as a resistor and a capactior in parallel: I have one resistor (12 Ohms) in parallel with a capacitor (10 Ohms), hence Resistance of the secondary load:

R= (R1*R2)/(R1+R2)
R=(10*12)/(10+12)= 5.45 Ohms Why should I assign turns to the independent windings? I added them together, hence my ration of turns n=700/1200

Are you supposed to calculate each separately? If yes why? *confused*
 
rude man said:
You might want to approach this problem from a basic-physics viewpoint: all you need is Faraday's and Ampere's laws.
1. what is the flux (easy)?
2. so what are the output voltages? (easy too)
3. and the currents thru C and R? (easy too, bit of algebra required)
4. finally, and more challenging: what is the primary current? this will include a phase other than 0.
I can't workout the flux since they had not given any information with regards to area or magnetic field.

Last question is intriguing, what do you mean by "phase other than 0"?
 
If asked for the reflected resistance, you won't involve the capacitor---it contributes reactance but no resistance.

Model the transformer secondary as two independent windings, 700 turns powering the resistor, and 300 turns connected to the capacitor.
 
Ahmed Bushra said:
The question is the following:

a) Determine all load voltages and currents
b) Determine the resistance reflected into the primary.

Answer a) R(l): 35V, 2.91A, X(cl): 15V, 1.5 A

The answer to part (b) is apparently 34.5 Ohms.
Where did you get the answers? From the text?

You seem sure of the answers to part a), but for part b) you say "apparently". Are you uncertain of the answer for part b)?
 
  • #10
Ahmed Bushra said:
View attachment 85342

b) Determine the resistance reflected into the primary.
What's reflected into the primary is not a resistance but an impedance.
 
  • #11
Ahmed Bushra said:
I can't workout the flux since they had not given any information with regards to area or magnetic field.
You don't need area or B field. What does Faraday's law say?
Last question is intriguing, what do you mean by "phase other than 0"?
I mean the primary current is not in phase with the primary voltage. The primary voltage phase is defined as zero.
 

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