Submitted by Landhund t3_z1o0qe in askscience
FourierXFM t1_ixcqhdi wrote
There's one thing I think most people are forgetting. Let's assume a power factor of 1.
Voltage is alternating (it is a sinusoid). Current is also alternating (it is also a sinusoid). The power is NOT alternating.
If power factor is 1, the current and voltage are in phase, which means they positive and negative at the same time.
So when voltage is positive, current is positive. Power = voltage * current, and both are positive, so power is positive.
When voltage is negative, current is negative. Power = voltage * current, and both are negative, so power is still positive.
_Tegridy_ t1_ixcv1by wrote
The real power is oscillating as well, it's just that the mean value of the real power is VIcos(theta).
There is a double frequency component of oscillating real power on top of it.
TrappedInASkinnerBox t1_ixcxt6j wrote
When the power factor is 1 the power (only real power here because of the pf) oscillates but isn't ever negative.
There's some coefficients in there but basically you square a sinusoidal waveform.
_Tegridy_ t1_ixcz2at wrote
Yes, that's what I was trying to get at. Power as such is oscillatory as well but when we talk of V I cos(theta), that's just the average real power over one cycle.
[deleted] t1_ixcvn8t wrote
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VulfSki t1_ixcz90r wrote
This is true. But it is still said to be alternating. Alternating current includes anything that is not DC. Even it is positive during the entire cycle it's still AC.
The confusion comes from the fact that people don't understand what alternating current means.
It doesn't mean energy flows back and forth. It means the voltage and the current are alternating. The voltage is a potential difference. The current is charge per second.
The power is traveling down the conductor in a waveform. Like a wave. So even though the charge carrying particles are moving back and forth, it is still delivering energy to the electrons on the other side of the circuit.
Like a light bulb. You send energy to the bulb in sinusoidal waves. The waves delivers energy to the device that is used to create light.
You don't deliver the particles themselves. It is the particles that move from one voltage potential to another that deliver energy to a load across that voltage potential.
An electron has a fixed charge. The energy itself comes from the votlage potential. Volts =Joules/Coulomb. Or in other words energy/charge.
The electrons can deliver the energy be moving from a high potential to a low potential. Thats why we refer to voltages as a potential. Cause it is like moving from a state of high potential energy to a low one.
So even though the charge moves back and forth it is still delivering energy in one direction (assuming a matched impedance)
FourierXFM t1_ixd0o2n wrote
I have never heard it that way. Alternate means to change direction. The power is not changing direction.
I have never heard someone call a DC voltage with a high frequency ripple as "alternating", even though that is kind of the same as what you're talking about.
People do say AC power a lot, but AC means alternating current, which is true. Not alternating power, which is not true (again, all assuming pf = 1).
I_dont_have_a_waifu t1_ixd7lhq wrote
See, in that situation, I'd say that there was a DC and AC component of the signal.
The AC component is the high frequency ripple, with an average value of zero. Then the total signal is the AC signal added to the DC signal.
VulfSki t1_ixd9umy wrote
Yes. I think in their example tho they are thinking about power supplies that rectify and the smooth ac into a useful DC signal. And on practical terms many people consider the ripple negligible and call it a DC power supply.
But I think they are coming from a pretty simplified explanation and then the added nuances don't exactly work with the simplified explanation
I_dont_have_a_waifu t1_ixda5h0 wrote
You're right, and it's not often that I would bother thinking much about the AC ripple on a power supply like that. I think the only I really gave it much thought was when I was designing rectifiers, and switching converters back in power electronics.
Otherwise I'd just throw a filter on it and call it a day.
[deleted] t1_ixdcpsp wrote
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VulfSki t1_ixd9hpq wrote
Then you learned it wrong. (Or just a simplified explanation) I have a bachelor's in EE, the standard convention for the terms is that any signal that is not DC is considered AC.
You can for example take any AC voltage and add a DC offset which then makes it so that the entire wave is positive through an entire period.
Nothing has changed about the signal, other than you have shifted the wave enough to no longer be negative, this is most certainly NOT a DC signal.
But it is entirely positive.
Take amplifiers for example as well, the transiistors in the output stage of a class A amplifier are biased in a way that the entire signal is positive. This obviously is not a DC signal.
The issue with thinking of AC signals as requiring to be both positive and negative is that all the meaningful conventions fall apart when you consider signals that are not centered around zero .
An ac signal with a DC offset will pass through capacitors, and then lose the DC component. The same way an AC signal, with a DC offset will not see an inductor as short.
What you refer to as having a little bit of ripple tells me you're thinking strictly in terms of power.
So yes when people rectify a signal and then try to smooth it to convert from AC to DC you can accept a small ripple in the signal. yes I definitely see how someone would call that a DC signal because that is what you are looking for in that case. And the ripple is small enough to not cause an issue. But of course depends on how precise your power needs to be.
So alternating having charge flows back and forth is not entirely wrong. But it's just overly simplified and in EE we consider any signal that it's not DC to be AC. Because that is a more useful convention in terms of how the laws of physics govern electro-magnetics. Because you can have alternating current signals that are entirely positive (or negative)
FourierXFM t1_ixdbot3 wrote
>Then you learned it wrong. (Or just a simplified explanation) I have a bachelor's in EE, the standard convention for the terms is that any signal that is not DC is considered AC.
I don't mean to get into a pissing contest, but you're being rude, so I will. I have a masters in EE with a specialty in power electronics focusing on AC/DC conversion. I promise I did not learn it wrong.
Alternating means back and forth, or positive and negative. A full bridge rectifier with no capacitive filter at the end is still called DC even though it's oscillating up and down.
At some point of ripple you would be more right to say it's DC with an AC component, but nobody in industry calls that alternating power... because it's not alternating.
VulfSki t1_ixdcxxb wrote
Yeah that's not what I'm talking about at all.
Yes I said it makes sense to consider that DC power. I never said otherwise there.
You seem to have misread my comment. What I said was that as a matter of convention, anything that isnt DC we called AC.
The phrase flowing back and forth can mean a number of things. My point was that it doesn't need to be negative to be considered AC.
When I work on power electronics, and still do, we often refer to the ripple at the output of the supply as an AC ripple as part of the DC. But yes of course we would never consider that an AC power supply. Of course we would still call that DC power. Sure.
Just to be clear. I said anything that isn't DC we refer to as AC. And you picked one very specific example to say "no everyone I talked to calls a DC power supply DC even if it has a ripple" which yeah or course they do. But that's not really related the point I was making
feint_of_heart t1_ixemxax wrote
> The power is traveling down the conductor in a waveform. Like a wave. So even though the charge carrying particles are moving back and forth, it is still delivering energy to the electrons on the other side of the circuit.
Damn it, I was following along until you said that. Can you explain how power moves in a wave in only one direction when the current and voltage is alternating?
VulfSki t1_ixepoh1 wrote
It has to do with the way that waves propagate through any medium.
The electromagnetic waves that travel down a conductor represent changes in the electromagnetic field across the charged particles. This does move the charge carriers. But it is the EM waves that are essentially transferring the energy.
For example, the rare at which the electricity travels down a copper wire is just about the speed of light. But the electrons themselves don't move that fast down the wire. They are accelerated back and forth and do drift down the conductor but the particles arent moving down the conductor at the speed of light. They move at what is called the drift velocity. Which is lower than it would take for you to walk. But that's because the energy is transferred via electromagnetic waves. It's not like a faucet or water where electrons flow like water.
And how you define how it flows in one direction depends on the scale. It does go back and forth but you can't violate the first law of thermodynamics. Power is energy over time. (Watts = Joules per second).
You can't have a passive load (the thing there needs electricity) sending energy back towards the generator (the thing that is making electricity) without violating the first law of thermodynamics. The one but caveat there is of course that the energy can be reflected back when it hits the load. That happens when the impedances don't match, which affects the power factor (which for the mathematically inclined is cosine of the phase angle between voltage and current.)
feint_of_heart t1_ixerjwd wrote
Ah, it just clicked. Thanks for taking the time to explain it :)
supra9710 t1_ixfryka wrote
Thank you that is very well said.
ImMrSneezyAchoo t1_ixe9a3w wrote
Power does not alternate only for 3 phase power (the math works out to have a literal constant power). In a single phase application p(t)=v(t)I(t) definitely can be an alternating signal, of varying complexity as the current changes its phase wrt voltage
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