Why no AC Panels

Re: Why no AC Panels

Cariboocoot wrote: »

Now someone is going to pipe up with "but there are AC panels!" and it will have to be explained that a panel with micro-inverter attached isn't really an "AC panel".

It seems some people are beginning to argue that an AC panel can have exposed DC conductors as long as the panel and micro-inverter go through a listing process together.

I'm sure they're saying that just to further confuse us all...

Re: Why no AC Panels

icarus wrote: »

Here is a question that belies my own ignorance. Why is it not possible for a panel to be designed to produce AC directly? The subject came in a conversation I recently had and wondered why one could do such a thing, and wouldn't that be an advantge in grid tie applications. For example if you could produce AC at a reliable frequency, then the only. (ha!) issue would be voltage regulation.

Very simply put, it's for the same reason that there are no AC batteries.

Re: Why no AC Panels

Cariboocoot wrote: »

putting "shutters" on PV's so they they pulsed on and off and produced a pseudo AC output.

WOW! Awesome idea! My next big project! This should be easy! My only question - the shutters I'm working on - - should I have them flap open and shut 60 times a second, or 120 times a second, and will the clatter be worse than the "wosh, wosh, wosh" of a wind turbine. And should I attach flex cables to the shutters so they won't fly off and go through the neighbors windows when the bearings fail?
You guys are the best and I await you're learned response.
Wayne :D:D

Re: Why no AC Panels

Oh Crap! There goes my idea of mechanical flappers. Hahahaha

Re: Why no AC Panels

Cariboocoot wrote: »

(Please don't anyone take this seriously!)

Hahaha The lighter side of solar power

Re: Why no AC Panels

ggunn wrote: »

There is no dark side of solar power. If it's dark, there's no power.

Hahaha Well man, ya got me there!!!!!!

Re: Why no AC Panels

icarus wrote: »

I guess that was sort of my point. Is there not technology out the however infect that could be integral to the PV to produce AC however cumbersome at this point? Is this a worth while endeavor and I wind if anyone is working on it, or is it just too much trouble? Going forward,,, who knows?

Tony

Going forward I see a DC future for home power. AC is increasing being turned to DC internally in even traditionally 60hz AC motor products like refrigeration so a native DC power buss, interconnects and smart power management is were technology is headed. We are starting to see hints of it in factory automation power management systems at work.

http://ecmweb.com/contractor/dc-house

http://www.cpes.vt.edu/public/showcase/d1.2FutureHome.php

Re: Why no AC Panels

Cariboocoot wrote: »

Tony;

When you look at the complexity of the existing systems (GT being the "simplest") you can see that squeezing it down to the panel
At the panel cell level, however, there's no way of getting AC pulses out of the semiconductor material at this point in time.

put the panel on a lazy susan, and spin it around very very fast :roll:

Re: Why no AC Panels

How about tubular modules (a la Solyndra) spinning at 60Hz? You could split the tube circumference into two banks of cells and capture their output separately. Unground the array and flip the polarity of half the tube. Each half would generate half the AC wave and the current waveform would taper to and from zero according to how much of its surface is exposed to sunlight. Handle the overlap with offset biasing the same way you handle the output of push and pull tubes in a class AB amplifier.

You heard it here first, folks!

Re: Why no AC Panels

Not to mention that - supposedly - while you get thrown off of AC if you accidentally touch it, you clamp down on DC so ... you never let go. Makes sense. So that's another strike against using DC as the standard. Not to mention the massive wires necessary if you stick with lower-voltage DC.

Re: Why no AC Panels

techntrek wrote: »

Not to mention that - supposedly - while you get thrown off of AC if you accidentally touch it, you clamp down on DC so ... you never let go. Makes sense. So that's another strike against using DC as the standard. Not to mention the massive wires necessary if you stick with lower-voltage DC.

One of those subjects where you can find an authoritative published source for any opinion you want to put forward.
Unambiguous (IMHO) common threads:

1. In terms of lethality of a given current for short exposure, AC in the 50/60 Hz range is more than four times as dangerous as DC in terms of setting the heart into fibrillation. (Defibrillators use a DC pulse to stop fibrillation and allow the heart to beat again.) Higher frequency AC (Tesla coil range) is much less harmful since it flows mainly on the surface layers of the body. But nobody will use that for power transmission.

2. If you just brush against the live conductor, DC is marginally more likely to throw you away from it. But if you grab the conductor, either AC or DC will cause muscle contractions that will keep you gripping the conductor with enough strength that a bystander (wearing insulated gloves) will have trouble pulling you away. Opinions differ about the relative strength of the contraction between AC and DC for the same current.

3. If there is a short circuit at very high voltage, DC is much harder to interrupt because the current does not pass through zero allowing the ionized air carrying the arc current to dissipate, preventing the arc from restarting. (Does anyone want to make comparisons between AC and DC arc welding?)

4. When swimming in electrified water, there is no question of "letting go" and the increased lethality of AC to the heart is the determining factor.

5a. Nobody will question that just comparing AC to AC or DC to DC, higher voltage is more dangerous as long as the current is not limited. (I see the rebuttals coming in already.....)
5b. But a high voltage source which is limited to a low current is less dangerous than a lower voltage source that can deliver more current through the body.