Bud-- wrote:
Jeff Wisnia wrote:

Beachcomber wrote:


snipped


In general terms, a three phase circuit is more powerful than a single
phase circuit because it delivers more power from point A to B per
unit of copper conductor and hence, is much more efficient.


I'm having difficulty following that one point, Beachcomber.

If by "unit of copper conductor" you mean the pounds of copper needed
to make the conductors going between points A and B, then;

It seems to me that for each indivdual conductor running between
points A and B, the power loss in that conductor is just going to be
equal to the rms current squared times the total resistance of the
conductor, and the power delivered to the load by that conductor is
going to be equal to the rms current times the rms voltage at the
load, assuming that the load has a unity power factor of course.

Those two powers (power loss and power delivered) remain the same
whether that conductor happens to be part of a single phase or a
multiphase transmission system, so the efficiency of the transmission
system (power delivered to the load less power lost in heating the
3000W supplie

conductors, divided by power entering the line) should be constant if
the voltage and pounds of copper used stay the same.

Comments?

Jeff

For single phase 120V line to neutral loads - common neutral, assume
1000W each load:
--Single phase supply 3wire (ABN) 2000W supplied
- 2000W/3 = 667 Watts per wire

Here's where I was coming from guys:

Say the 2000W load is composed of two 1000W loads in series, connected
across that single phase 240V supply.

So, there's zero current in the neutral.

And, each of the two wires (A&B) is carrying 2000/240 = 8.33 Amps.

Thus the line losses (in Watts) are equal to that current times the
resistance of each wire. Let's assume 1 ohm resistance in each wire, so
the total line losses for the two wires (AB) will be 16.66W while
powering a 2000W load.

Now take the 3 phase supply (208/120V) 4 wire (ABCN), and let the load
be three 1000 watt loads connected in a star pattern, dissipating a
total of 3000 watts. (It's easier for me to do visualize current flows
with a star rather than a delta.)

Because everything is balanced there's zero current in the neutral in
this case too.

The current in each of the three wires (ABC) is 1000/120 = 8.33 Amps,
just like the single phase example. If they are the same 1 ohm wires,
the total line losses for the three wires (ABC) are 24.99 Watts


Now, 2000/3000 = 16.66/24.99, so the "power tranmission efficiency" per
wire is the same, IF the loads are balanced and you can get away WITHOUT
a neutral wire.

I agree that's not usually a code permitted case, so 'ya got me on the
"wire count efficiency" if the neutral has to be there, even though it's
not carrying any current and dissipating any losses.

Jeff


--3 phase supply (208/120V) 4 wire (ABCN) 3000W supplied
- 3000W/4 = 750 Watts per wire - 12% higher

For 3 phase 240V line to line loads - assume 10A per wi
--Single phase supply 2 wire (AB)- watts supplied = 2400W
- 2400W/2 = 1200 Watts per wire
--3 phase supply (240V delta) 3 wire (ABC) watts supplied = 10 X 240 X
SQR(3) = 4157W mo
- 4157/3 = 1386 watts per wire - 15.5% higher

3 phase is also a significant advantage in all but small motors. Also
can be in power supplies.

bud--


--
Jeffry Wisnia

(W1BSV + Brass Rat '57 EE)

"Truth exists; only falsehood has to be invented."