Why is residential wiring known as single phase?

Besoeker · Jan 31, 2012

T.M.Haja Sahib said:
I simply answered to your post #64 via my post # 95.

My #64 showed 120-0-120.
Not 0-120-240.

Besoeker · Jan 31, 2012

rattus said:
A "phase" (noun) must be generated by its own generator.

Three-phase generators are actually quite common......

T.M.Haja Sahib · Jan 31, 2012

Besoeker said:
My #64 showed 120-0-120.
Not 0-120-240.

The only way to prove which one is correct either 120-0-120 or 0-120-240v is to measure the currents in two outdoor conductors and the neutral for equal loads.
Well-equipped,you could easily do it...........

Besoeker · Jan 31, 2012

T.M.Haja Sahib said:
The only way to prove which one is correct either 120-0-120 or 0-120-240v is to measure the currents in two outdoor conductors and the neutral for equal loads.
Well-equipped,you could easily do it...........

Why on earth would you want do that when it's a matter of a quite simple calculation?
As shown in post #64.
If, for example, the two loads are resistive and the currents balanced in each winding, the current in the neutral will be zero.

kwired · Jan 31, 2012

about 20% of the way to 600 posts

T.M.Haja Sahib · Jan 31, 2012

Besoeker said:
If, for example, the two loads are resistive and the currents balanced in each winding, the current in the neutral will be zero.

How it can be?If there are two opposite phases,the current in the neutral is double.

Besoeker · Jan 31, 2012

T.M.Haja Sahib said:
Please do it,if you can.You will be taken aback by the result.

Why?
It will be entirely in line with expectations.

Besoeker · Jan 31, 2012

kwired said:
about 20% of the way to 600 posts

Amazing, innit?
Especially since the discussion is being conducted mainly by two furriners........

david luchini · Jan 31, 2012

T.M.Haja Sahib said:
How it can be?If there are two opposite phases,the current in the neutral is double.

No it won't be double, precisely because the load currents are "opposite."

The current in the neutral will be In=Ia+Ib.

If Ia=10A at an angle of zero, and Ib=10A at an angle of 180 (180 is "opposite" of zero), then

In=Ia+Ib=10<0 + 10<180 = 0

T.M.Haja Sahib · Jan 31, 2012

david luchini said:
No it won't be double, precisely because the load currents are "opposite."

The current in the neutral will be In=Ia+Ib.

If Ia=10A at an angle of zero, and Ib=10A at an angle of 180 (180 is "opposite" of zero), then

In=Ia+Ib=10<0 + 10<180 = 0

Take into account the sine of 180 is -1 and the two current vectors are in opposite direction.So the net current through neutral should be difference of one positive vector and one negative vector.The result is double.

Besoeker · Jan 31, 2012

T.M.Haja Sahib said:
Take into account the sine of 180 is -1 and the two current vectors are in opposite direction.So the net current through neutral should be difference of one positive vector and one negative vector.The result is double.

Sorry. That's just plain wrong.

david luchini · Jan 31, 2012

T.M.Haja Sahib said:
Take into account the sine of 180 is -1 and the two current vectors are in opposite direction.So the net current through neutral should be difference of one positive vector and one negative vector.The result is double.

Huh?:?

The sine of 180 is zero, not -1.

But the cosine of 180 is -1, and the cosine of zero is 1.

That's why the current in the neutral will be zero.

In=Ia+Ib=10<0 + 10<180 = (1)*(10) + (-1)*(10) = 0.

T.M.Haja Sahib · Jan 31, 2012

david luchini said:
Huh?:?

The sine of 180 is zero, not -1.

But the cosine of 180 is -1, and the cosine of zero is 1.

That's why the current in the neutral will be zero.

In=Ia+Ib=10<0 + 10<180 = (1)*(10) + (-1)*(10) = 0.

Sorry I blundered.

jim dungar · Jan 31, 2012

david luchini said:
No it won't be double, precisely because the load currents are "opposite."

The voltages are opposite so they add, the currents are opposite so they subtract.:?
So far we have proved that Vnb=-Vbn, pretty cutting edge stuff.

How about solving the equations involved in typical center tapped circuits where the neutral is not common to all of the loads. The one I have asked about previously is a standard 3-wire stove, one load (say 1A) connected L1-N and a resistive load (say 30A) connected L1-L2. Then add a third load (say 10A) from L2-N. Are all of your voltages and currents 'in phase' with each other? Have values changed simply because a neutral point exists?

david luchini · Jan 31, 2012

jim dungar said:
The voltages are opposite so they add, the currents are opposite so they subtract.:?

:? When did I say anything like that? By the way "opposite" was T.M's word, not mine. That's why I put it in quotes.

I said the load on the neutral would be the sum of the current Ia & Ib: In=Ia+Ib.

jim dungar said:
How about solving the equations involved in typical center tapped circuits where the neutral is not common to all of the loads. The one I have asked about previously is a standard 3-wire stove, one load (say 1A) connected L1-N and a resistive load (say 30A) connected L1-L2. Then add a third load (say 10A) from L2-N. Are all of your voltages and currents 'in phase' with each other?

Assuming all your loads are resistive: IL1=31<0A, IL2=40<180A and In=9<180A

jim dungar said:
Have values changed simply because a neutral point exists?

Yes, I think they have. Without the neutral point, it would be difficult to connect the loads from line to neutral. If we left the loads from your example and disconnected the circuit at the neutral point, the currents would change to IL1=31.82<0, IL2=31.82<180 and In=0.

jim dungar · Jan 31, 2012

david luchini said:
:? When did I say anything like that? By the way "opposite" was T.M's word, not mine. That's why I put it in quotes.

I said the load on the neutral would be the sum of the current Ia & Ib: In=Ia+Ib.

The major discussion has been that the voltages are out of phase and therefore combine to a larger number. Now you are saying that the currents are out of phase and are combining to a smaller number.

Assuming all your loads are resistive: IL1=31<0A, IL2=40<180A and In=9<180A

I would like you to show the current and voltages for situation #1 (2 loads) including the source voltages.
Then show the currents and voltages for situation #2 (3 loads).

Did any of the 'math' need to be modified when the source neutral point became common to multiple loads?

Joethemechanic · Jan 31, 2012

So if we decide that "single phase" is now to be called "two phase"

What are we going to call this then?

K8MHZ · Jan 31, 2012

Joethemechanic said:
So if we decide that "single phase" is now to be called "two phase"

What are we going to call this then?

Oh, look! There is the square root of 2!

Besoeker · Jan 31, 2012

jim dungar said:
How about solving the equations involved in typical center tapped circuits where the neutral is not common to all of the loads. The one I have asked about previously is a standard 3-wire stove, one load (say 1A) connected L1-N and a resistive load (say 30A) connected L1-L2. Then add a third load (say 10A) from L2-N.

Your request is my....etc...

Currents:

Relationships:

Joethemechanic · Jan 31, 2012

K8MHZ said:
Oh, look! There is the square root of 2!

lol, how did I miss that. BTW, here in Philly we did two phase the correct way, we used a 5 wire service. None of that messing around with that silly square root of two and the neutral that wasn't really a neutral that those places that had 3 wire 2 phase had to do.

Why is residential wiring known as single phase?

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