Transformers - Variation in Current, EMF and Magnetic FLux

In summary: The voltage and current will still be 180 degrees out of phase, but the waveforms will not be perfectly sinusoidal anymore.
  • #1
elemis
163
1
This question about the variation of the aforementioned quantities in a transformer.

Now according to me and my knowledge of electricity this is how I feel it should play out :

If the input current were a sine curve that varies with time then :

Input voltage = cosine curve i.e. it is ahead of input current by 90 degrees.

Magnetic Flux = sine curve with same period as input voltage but LARGER amplitude.

Output voltage = out of phase with input voltage by 180 degrees.

Output current = this is where I'm faltering and I'm having issues...

Could someone please confirm what I've said is correct and help me with the bit in bold ?
 
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  • #2
Could someone also confirm if voltage = rate of change of current with time ?
 
  • #3
Bump.
 
  • #4
Hmmmmmm...interesting question.

I don't know the exact answer...but will just throw out some thoughts.

I know if you have a purely resisitive load hooked to a transformer...the voltage and current appear to be in perfect phase on the secondary...and primary. But as you are saying...the primary and secondary should be out of phase by 180 degrees since the secondary pumps current the other direction.

But the coil's inductive property says it will lag the current behind the voltage...

I'll be interested to see what the smart guys have to say.
 
  • #5
Are you considering a ideal transformer with a load
or
A NON ideal transformer with no load?
A NON ideal transformr with a load will have answers to your question that depend on the load.
 
  • #6
Carl Pugh said:
Are you considering a ideal transformer with a load
or
A NON ideal transformer with no load?
A NON ideal transformr with a load will have answers to your question that depend on the load.

You have to understand that I'm an A Level student i.e. the equivalent of an American High School student.

Anyways, we've only been considering IDEAL transformers where we are told the is a Primary coil voltage and secondary coil voltage. We are never shown the presence of a load.

So, I'm guessing I want to know about an IDEAL transformer with NO load ?
 
  • #7
elemis said:
You have to understand that I'm an A Level student i.e. the equivalent of an American High School student.

In that case, this question should be answered in Homework section.

Anyway.. In academic approach an "ideal transformer" means that:
- we neglect the resistance of the windings -> the transformer has efficiency equal to 1 (Pin = Pout),
- we assume that the schematic of transformer contains only two coils (primary and secondary),
- current and voltage on both sides are connected only by turn ratio of coils,
- all waveforms (current, voltage, flux) are assumed to be sinewave,

Flux can be calculated from Faraday's law of induction. In this case (only inductances in schematic of transformer) we have:

Uprimary - 0 deg
Flux and I primary - 90 deg
U secondary - 180 deg
I secondary and counter flux - 270 deg
elemis said:
Magnetic Flux = sine curve with same period as input voltage but LARGER amplitude.
?
Please tell me, how can You compare amplitude of flux and voltage ? Volts vs Webers ? Amplitude of flux depends on voltage and magnetic circuit as said below:

Induction * Cross.section = Flux = Voltage / (4,44 * Frequency * Turn.ratio)

That's in theory - means BIG simplifications.
 
  • #8
gerbi said:
In that case, this question should be answered in Homework section.

Well, this isn't a homework question. Its me trying to further my knowledge in the subject.

gerbi said:
Anyway.. In academic approach an "ideal transformer" means that:
- we neglect the resistance of the windings -> the transformer has efficiency equal to 1 (Pin = Pout),
- we assume that the schematic of transformer contains only two coils (primary and secondary),
- current and voltage on both sides are connected only by turn ratio of coils,
- all waveforms (current, voltage, flux) are assumed to be sinewave,

Flux can be calculated from Faraday's law of induction. In this case (only inductances in schematic of transformer) we have:

Uprimary - 0 deg
Flux and I primary - 90 deg
U secondary - 180 deg
I secondary - 270 deg

What do you mean by U Primary ? Is that the voltage across the primary coil ? Do you mean 90 degrees ahead of U Primary or lagging behind ?
 
  • #9
elemis said:
What do you mean by U Primary ? Is that the voltage across the primary coil ? Do you mean 90 degrees ahead of U Primary or lagging behind ?

Uprimary is primary voltage (on primary coil).
Leading or lagging ? We consider coils here - currents are lagging.
 
  • #10
gerbi said:
Uprimary is primary voltage (on primary coil).
Leading or lagging ? We consider coils here - currents are lagging.
To be honest you're only confusing me.

Could you have a look at my post and tell me whether what I've said is correct or wrong ?
 
  • #11
elemis said:
To be honest you're only confusing me.

Could you have a look at my post and tell me whether what I've said is correct or wrong ?

That's why this questions should be answered in Homework section.

Uprimary means voltage measured between both terminals of a coil.

Currents in both windings are 90 deg behind voltages (currents are lagging).
 
  • #12
In an ideal transformer with no load:
There would not be any primary or secondary current.
Magnetic flux would lag the applied voltage by 90 degrees.
Magnetic flux and voltage are in different units, so you cannot say one is larger than the other.
Output voltage phase depends on how the transformer is connected. Some engineers might say that input voltage and output voltage are 180 degrees out of phase. I consider output voltage and input voltage in phase.
 
  • #13
Carl Pugh said:
In an ideal transformer with no load:
There would not be any primary or secondary current.
Magnetic flux would lag the applied voltage by 90 degrees.
Magnetic flux and voltage are in different units, so you cannot say one is larger than the other.
Output voltage phase depends on how the transformer is connected. Some engineers might say that input voltage and output voltage are 180 degrees out of phase. I consider output voltage and input voltage in phase.

They are techinically out of phase by 180 degrees...but who cares? So what you are saying is more or less true. When you hook up your load to your secondary...the voltage and current are in phase...and the reference point of you voltage is what it is. Referring back to the primary phase of the voltage doesn't do you any good unless you are playing with math. In the field...this info won't help you.

To elemis...since you are at a high school level...keep things simple. The turns ratio...power in = power out...and the formula for computing the resistance from the secondary back to the primary should be all you need at this point. Until these things are mastered...don't move on quite yet.
 
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  • #14
Some high schools teach enough calculus to have covered that derivative of a sinewave is a cosine wave.

My high school did not. At least before 12th grade.
Our Electronics teacher taught us 10th grade boys that sine and cosine waves are same shape but shifted 90deg and we worked the circuit problems using operator j which shifted 90 degrees. So two 90 degree phase shifts = 180 deg phase shift, which reverses polarity, which is same as multiplying by -1, so operatorj we thought of as √-1. We worked our problems in simple algebra using rectangular and polar notation . Became skilled at conversions by slide rule .

We had one guy in class who was somewhat of a prodigy and he worked the problems via math resembling Eueler's identity . He was way ahead of us ordinary kids.

So if you haven't taken calculus yet that's okay, you will. Meantime I'm sure you are aware the cosine wave is a plot of the slope of a sine wave and vice versa.

Your understanding of the transformer is pretty good.
Re polarity we indicate polarity on a schematic diagram by dots on the ends of the windings that go positive at same time. In practice you find it with a battery and multimeter.


Point of all this - you seem to have a good start !
Curiosity - are you taking an electronics course in high school or is this your own hobby?

old jim
 
  • #15
jim hardy said:
Some high schools teach enough calculus to have covered that derivative of a sinewave is a cosine wave.

My high school did not. At least before 12th grade.
Our Electronics teacher taught us 10th grade boys that sine and cosine waves are same shape but shifted 90deg and we worked the circuit problems using operator j which shifted 90 degrees. So two 90 degree phase shifts = 180 deg phase shift, which reverses polarity, which is same as multiplying by -1, so operatorj we thought of as √-1. We worked our problems in simple algebra using rectangular and polar notation . Became skilled at conversions by slide rule .

We had one guy in class who was somewhat of a prodigy and he worked the problems via math resembling Eueler's identity . He was way ahead of us ordinary kids.

So if you haven't taken calculus yet that's okay, you will. Meantime I'm sure you are aware the cosine wave is a plot of the slope of a sine wave and vice versa.

Your understanding of the transformer is pretty good.
Re polarity we indicate polarity on a schematic diagram by dots on the ends of the windings that go positive at same time. In practice you find it with a battery and multimeter.


Point of all this - you seem to have a good start !
Curiosity - are you taking an electronics course in high school or is this your own hobby?

old jim
Actually, this is simply part of the A Level (British Curriculum) syllabus for Physics.
 
  • #16
I know that this is starting an argument like discussing politics or religion, but what the heck.

I say the polarity of the input winding is the same as the output winding because.
You can wind a transformer with two wires at the same time. (bifilar winding)
The start of both wires can be connected together and the end of both wires can be connected together.
This winding can be used as the primary (or secondary) of the transformer.
Thus both wires have the same polarity.
Now you can disconnect one wire and have a secondary. The polarity hasn't changed, so the polarity of the primary and the secondary is the same.
 
  • #17
Actually, this is simply part of the A Level (British Curriculum) syllabus for Physics.

I was in high school in 1961-1964.

Sounds like your physics is more comprehensive than was ours.
That's good. This is the age of technology and i believe education system should prepare us for the world we live in. The high school i attended was experimenting with that concept. I was very fortunate. It gave me a running start at engineering school.

We also studied a year of English Literature. Does your syllabus include any American lit ?

old jim
 
  • #18
jim hardy said:
I was in high school in 1961-1964.

Sounds like your physics is more comprehensive than was ours.
That's good. This is the age of technology and i believe education system should prepare us for the world we live in. The high school i attended was experimenting with that concept. I was very fortunate. It gave me a running start at engineering school.

We also studied a year of English Literature. Does your syllabus include any American lit ?

old jim
Well then, that's a loooong time ago :D

The British curriculum is very different in the sense we have a year 12 and 13.

Where an American child is doing the SATs we do the A Level.

At A Level you can choose any number of subjects of any combination to be examined under. Obviously, if you're going to study Chemistry (like me) you would do Chemistry, Physics, Maths and (if you wanted to) Literature (I did Further Maths instead).
 
  • #19
jim hardy said:
I was in high school in 1961-1964.

Sounds like your physics is more comprehensive than was ours.
That's good. This is the age of technology and i believe education system should prepare us for the world we live in. The high school i attended was experimenting with that concept. I was very fortunate. It gave me a running start at engineering school.

We also studied a year of English Literature. Does your syllabus include any American lit ?

old jim
Out of interest, what happened to that high school prodigy you mentioned ? Did he go on to do something great ?
 
  • #20
Carl Pugh said:
I know that this is starting an argument like discussing politics or religion, but what the heck.

I say the polarity of the input winding is the same as the output winding because.
You can wind a transformer with two wires at the same time. (bifilar winding)
The start of both wires can be connected together and the end of both wires can be connected together.
This winding can be used as the primary (or secondary) of the transformer.
Thus both wires have the same polarity.
Now you can disconnect one wire and have a secondary. The polarity hasn't changed, so the polarity of the primary and the secondary is the same.

This is not true with all transformers.

I think that physics is not like a religion or politics. Laws works always the same way no matter what. No matter what each engineer say or think, we must obey to the same laws.

Imagine this bifilar winding - same polarity on both wires. Now switch terminals on one of the windings.. and we have voltages in counterphase (180 deg).

Any further discussion about primary and secondary voltages in phase or in counterphase should start from stating how windings are connected. This is the real issue here.

And sorry guys.. but problem of winding connection is one of the main issues when connecting transformer to the grid. Don't underestimate it and don't tell this is only important while doing math.

Little summary as threat starter wished.

elemis said:
Input voltage = cosine curve i.e. it is ahead of input current by 90 degrees.?
True
elemis said:
Magnetic Flux = sine curve with same period as input voltage but LARGER amplitude.
Not true. Flux is in phase with primary current and in counterphase of secondary current. Do not compare amplitudes of different physical quantities.
elemis said:
Output voltage = out of phase with input voltage by 180 degrees.
Basically true (for an ideal transformer) but can be 0 deg when You simply switch terminals.
elemis said:
Output current = this is where I'm faltering and I'm having issues...
Output current is in counter phase to primary current and 90 deg behind secondary voltage.

Edit: This all applies to ideal transformer only with pure inductive load.

As stated in posts below - angle between current and voltage depends solely on load as an ideal transformer has no resistance and no reactance (there is no leakage flux).
 
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  • #21
Well, we have to separate magnetizing current from load current.

an IDEAL transformer could have zero magnetizing current

but a real one must have some.

Magnetizing current is in phase with flux and 90deg out of phase with primary voltage

But load current has phase determined by nature of the load. If load is resistive then load current is in phase with terminal voltage. Observe that load current flows in both primary and secondary , in proportions set by turns ratio of course.

My mental model uses an ideal transformer with infinite indutcance hence it draws no magnetizing current.
Some people prefer to use in their model an ideal transformer with finite inductance and consider the magnetizing current.
Note that if you do that your ratio of primary to secondary currents will be different than the ratio of primary to secondary turns by the amoount of magnetizing current. That's because magnetizing current flows only in primary. It is small compared with load current so is usually neglected in power transformers. It is accounted for in current transformers by tweaking the turns ratio.



So i'd have to raise my eyebrows at this one :
Output current is in counter phase to primary current and 90 deg behind secondary voltage
.

old jim
 
  • #22
jim hardy said:
an IDEAL transformer could have zero magnetizing current
It has no magnetizing current since only elements of transformer schematic are the coils (there is no transverse branch in schematic). Let's keep it this simple here.

jim hardy said:
But load current has phase determined by nature of the load. If load is resistive then load current is in phase with terminal voltage. Observe that load current flows in both primary and secondary , in proportions set by turns ratio of course.
That's true, ofcourse. Phase between voltage and current (both primary and secondary) are determined by the load since transformer acts just like a simple 'electrical gear' (divides and multiplies current/voltage by turn ratio).


jim hardy said:
That's because magnetizing current flows only in primary.
Not true in practice. In short.. Power transformers with star connected winding have usually secondary connected in delta (or have third, 'compensating' winding) so higher harmonic magnetizing currents can circulate (flux in core is more sinusoidal then).

jim hardy said:
So i'd have to raise my eyebrows at this one : .
old jim
What would be flux look like if the currents wouldn't be in counterphase ?

About that 90deg - got that now. Ideal transformer has no resistance and no reactance (there is no leakage flux). It's simply a 'electrical gear'. So phase shift between current and voltage on primary side (secondary side as well) will depend only on load. Thanks for that jim and sorry for my mislead.
 
  • #23
Not true in practice. In short.. Power transformers with star connected winding have usually secondary connected in delta (or have third, 'compensating' winding) so higher harmonic magnetizing currents can circulate (flux in core is more sinusoidal then).

Ahh yes, the tertiaries. Often used to power the cooling fans and oil circulators.
Good one !
So i'd have to raise my eyebrows at this one : (...""counter phase to primary current and 90 deg behind secondary voltage...) ""'


What would be flux look like if the currents wouldn't be in counterphase ?

it's the 90 deg i was questioning not the counterphase. My bad, Big ten-oops there.
And you answered that part already .

Thanks !

old jim

Elemis - the prodigy kid got a scholarship to a big name unversity. I lost track of him. In fact have forgotten his last name , i knew him only as Fabio. I will see if i can find my yearbook and track him down. Thanks !
 
  • #24
i see what you mean now, what i wrote would only constitute an inductive load. obviously that's not the only case
 
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  • #25
FOIWATER said:
Then your secondary current is always ninty degrees behind your output voltage regardless of reference

Please feed us with math that stands behind this because now I have some big dilemma.
Remember about this things:
- we are discussing ideal transformer,
- there is no resistance in ideal transformer,
- there is no leakage reactance in ideal transformer (as there is no leakage flux),
- coils in schematic of ideal transformer indicates perfect magnetic coupling.
 
  • #26
Then your secondary current is always ninty degrees behind your output voltage

if 'output voltage' means 'secondary voltage' then i don't buy it either.
 
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  • #27
jim hardy said:
if 'output voltage' means 'secondary voltage' then i don't buy it either.

Obviously this is wrong. Delivering only Vars to everyone would not work out so well.
 
  • #28
well then the output depends on the load connected?

I would say the information you have written for your primary variables is correct, and I guess I sort of got tangled up trying to relate them to the secondary, but the secondary current depends on load connected..

although, what i wrote previously about polarity is still correct.

no load - no current
resistive load - the voltage current are in phase
capacitive load - the output current will lead the output voltage, but with reference to the primary, it depends on your polarity markings.
inductive load - the output current will lag the output voltage, but with reference to the primary, it depends again on polarity markings.

http://www.allaboutcircuits.com/vol_2/chpt_9/4.html <--- this page cites the two voltages as in phase, unless you reverse your output coil. It states that the coil polarity for practical scenario's is ambigious... and also explains the polarity markings I made reference to.

http://www.allaboutcircuits.com/vol_2/chpt_9/1.html <--- i agree with gerbi as well, saying to the OP that the magnetic flux is not in phase with the primary voltage but in phase with the injected current, but yes it is of a larger magnitude.

any corrections welcomed.
 
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  • #29
gerbi said the conditions were a perfect transformer with no load.
In a perfect transformer with no load.
There is no primary current and no secondary current.
The secondary voltage in just the turns ratio times the primary voltage.
The magnetic flux lags the primary voltage by 90 degrees. (Since there is no primary current, it doesn't make sense to say that the flux leads or lags the current)

If there is a load, the primary current is the secondary current/the turns ratio.

E1/E2=N1/N2
I1/I2=N2/N1

E1=primary voltage
E2=secondary voltage
N1=primary turns
N2=secondary turns
I1=primary current
I2=secondary current

gerbi, a good check of your calculations for a perfect transformer is that the input watts should equal the output watts.
 
  • #30
Opps made a mistake
the primary current is the secondary current X the turns ratio.
 
  • #31
Nice, Carl.

Gerbi's example in #20 of the bifilar winding is a good reference point to keep thinking straight.

I was taught ~1961 about a phase reversal but for the life of me can't recall why.
Unloaded, Flux will be integral of primary voltage and secondary voltage the derivative of Flux.

Does taking the derivative of an integral not simply get you back where you started?
Volts = sin
∫(sin) = -cos
d(-cos) = +sin

I wonder if the confusion stems simply from drawing a transformer with windings shown on opposite sides of the window as in this hyperphysics link.
http://hyperphysics.phy-astr.gsu.edu/hbase/magnetic/transf.html

transf.gif


Observe flux leaves the dotted end of primary but enters dotted end of secondary. [EDIT oops no dots on that drawing but wrap your right-hand fingers around core in same direction as current through winding and thumb points in direction of MMF]

In your mind's eye flip that secondary over so it's just above the primary and observe it's wound in opposite direction.
From the TOP view primary is THEN wound CCW and secondary is wound CW.

old jim
 
  • #32
Jim,

Those were my thoughts as well. There clearly is a phase shift on the primary coil...but there is also a phase shift on the secondary coil which must put it back. Don't know that math...but it must be true because sure enough the voltage is in phase with the current on any oscilliscope thru a purely resistive load. Starting with a power factor of 1
is most convenient.
 
  • #33
The polarity of a transformer can be determined from which direction the wire enters the core.
In the picture Jim place above, Ip could be replaced with a polarity dot.
Is could be replaced with a polarity dot.
The polarity dots would be correct.

In the picture above, if the secondary conductor entered from the back of the core and exited from the front of the core (opposite to that shown), the secondary polarity mark would be near Ns.

Assuming a perfect transformer and a resitive load, could the confusion be because the transformer primary is a load, so the current and voltage have to be in phase.
In the other case the transformer is a power source so the current in the secondary has to be 180 degrees out of phase with the voltage in the secondary.
 
  • #34
elemis said:
Could someone also confirm if voltage = rate of change of current with time ?

no, voltage can not be equal to the rate of change of current with time.as it will violate the ohm's law. according to which the current flowing in a conductor is directly proportional to the voltage across it.
 
  • #35
elemis said:
This question about the variation of the aforementioned quantities in a transformer.

Now according to me and my knowledge of electricity this is how I feel it should play out :

If the input current were a sine curve that varies with time then :

Input voltage = cosine curve i.e. it is ahead of input current by 90 degrees.

Magnetic Flux = sine curve with same period as input voltage but LARGER amplitude.

Output voltage = out of phase with input voltage by 180 degrees.

Output current = this is where I'm faltering and I'm having issues...

Could someone please confirm what I've said is correct and help me with the bit in bold ?

but what do you want to ask in it?
 
<h2>1. What is the relationship between current and magnetic flux in Transformers?</h2><p>The relationship between current and magnetic flux in Transformers is described by Faraday's Law of Induction. This law states that the induced electromotive force (EMF) in a circuit is equal to the rate of change of magnetic flux through the circuit. Therefore, as the current in a transformer changes, it produces a changing magnetic flux that induces an EMF in the secondary coil.</p><h2>2. How does the variation in current affect the performance of a transformer?</h2><p>The variation in current affects the performance of a transformer by creating a varying magnetic field, which in turn induces an EMF in the secondary coil. This EMF can be used to step up or step down the voltage in the secondary coil, depending on the number of turns in each coil. However, if the current varies too much, it can lead to overheating and damage to the transformer.</p><h2>3. What factors influence the variation in current in a transformer?</h2><p>The variation in current in a transformer is influenced by several factors, including the number of turns in the primary and secondary coils, the frequency of the alternating current, and the magnetic properties of the core material. Additionally, the load on the secondary coil and the resistance of the wires also affect the variation in current.</p><h2>4. How does the magnetic flux in a transformer change with the variation in current?</h2><p>The magnetic flux in a transformer changes with the variation in current due to the relationship described by Faraday's Law of Induction. As the current in the primary coil changes, it produces a changing magnetic field that induces an EMF in the secondary coil. This EMF, in turn, causes a variation in the magnetic flux through the transformer.</p><h2>5. What are some practical applications of understanding the variation in current, EMF, and magnetic flux in transformers?</h2><p>Understanding the variation in current, EMF, and magnetic flux in transformers is crucial for various practical applications. Some examples include power transmission and distribution, where transformers are used to step up the voltage for efficient transmission and then step it down for safe use in homes and businesses. Transformers are also used in electronic devices to convert AC to DC and vice versa, and in electric motors to regulate the speed and torque. Additionally, understanding these principles is essential for designing and maintaining efficient and safe electrical systems.</p>

1. What is the relationship between current and magnetic flux in Transformers?

The relationship between current and magnetic flux in Transformers is described by Faraday's Law of Induction. This law states that the induced electromotive force (EMF) in a circuit is equal to the rate of change of magnetic flux through the circuit. Therefore, as the current in a transformer changes, it produces a changing magnetic flux that induces an EMF in the secondary coil.

2. How does the variation in current affect the performance of a transformer?

The variation in current affects the performance of a transformer by creating a varying magnetic field, which in turn induces an EMF in the secondary coil. This EMF can be used to step up or step down the voltage in the secondary coil, depending on the number of turns in each coil. However, if the current varies too much, it can lead to overheating and damage to the transformer.

3. What factors influence the variation in current in a transformer?

The variation in current in a transformer is influenced by several factors, including the number of turns in the primary and secondary coils, the frequency of the alternating current, and the magnetic properties of the core material. Additionally, the load on the secondary coil and the resistance of the wires also affect the variation in current.

4. How does the magnetic flux in a transformer change with the variation in current?

The magnetic flux in a transformer changes with the variation in current due to the relationship described by Faraday's Law of Induction. As the current in the primary coil changes, it produces a changing magnetic field that induces an EMF in the secondary coil. This EMF, in turn, causes a variation in the magnetic flux through the transformer.

5. What are some practical applications of understanding the variation in current, EMF, and magnetic flux in transformers?

Understanding the variation in current, EMF, and magnetic flux in transformers is crucial for various practical applications. Some examples include power transmission and distribution, where transformers are used to step up the voltage for efficient transmission and then step it down for safe use in homes and businesses. Transformers are also used in electronic devices to convert AC to DC and vice versa, and in electric motors to regulate the speed and torque. Additionally, understanding these principles is essential for designing and maintaining efficient and safe electrical systems.

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