Behemot wrote:Did I miss what is it for?
LongRunner wrote:
- If the neutral conductor breaks (or a plug just creeps loose) upstream of the power strip, then the load current will take a detour through the MOV to earth; if the circuit is on an RCD/GFCI that will trip immediately
- If you plug one into an outlet without an intact earth connection, whilst touching the casing of a Class I appliance (this definitely includes your desktop PC!) plugged into the computer murderer – and the active/hot pin makes contact before the neutral, and any appreciable load is switched on (one incandescent lamp or electric blanket is ample, never mind a space heater) – then you'll get electrocuted (or shocked at the very least).
That section is specifically about the frightening U.S. versions, as I wrote immediately above:Behemot wrote:LongRunner wrote:
- If the neutral conductor breaks (or a plug just creeps loose) upstream of the power strip, then the load current will take a detour through the MOV to earth; if the circuit is on an RCD/GFCI that will trip immediately
- If you plug one into an outlet without an intact earth connection, whilst touching the casing of a Class I appliance (this definitely includes your desktop PC!) plugged into the computer murderer – and the active/hot pin makes contact before the neutral, and any appreciable load is switched on (one incandescent lamp or electric blanket is ample, never mind a space heater) – then you'll get electrocuted (or shocked at the very least).
MOV being a voltage-dependent semiconductor only opens after reaching the treshold for it to become conductive. When the neutral fails, nothing will happen as the MOV will still have resistance somewhere in the vicinity of megaohms. Some tiny currents may flow through it (as they always do), as well as through leaking Y capacitors. It that sums to high enough current, RCD will kick in and shut the circuit down.
You get electrocuted because of leaking Y capacitors, induction (SMPS does induce some currents in the metal casing/shielding) and bad transformer insulation, not because of MOVs. Those usually have much lower leakages than Y capacitors, as known from class II/defect class I bricks powering laptops and similar equipment which sometimes give some ppl shocks (especially the metal ones). The voltages usually reach about 50-100 V so you can feel it but the currents are very low and (usually) harmless.
I was not claiming that particular danger applied to the Australian versions (as shown).I wrote:At least in these Australian versions, the neutral—earth MOV is rated to withstand the full mains voltage. In the USA (which probably has, in general, the least safe electrical system of any "first world" country), even that doesn't necessarily apply. This introduces two major further dangers:
Zero Surge explains the problem very clearly indeed. In a nutshell:Behemot wrote:In general, I do not really see any problem with MOVs on ground, good surge protectors and UPS usually still have those, just the cheapos don't (to save costs). While line-neutral MOV is usually enough, not always, especially with distrasous surges when the normal-mode MOV immediatelly vaporizes it could help to conduct another small part of the impuls to the ground.
And in more detail:Zero Surge wrote:By sending surges to the ground line, the voltage rise on the ground can disrupt audio, video, data and communications signals and also damage interconnected equipment.
Zero Surge wrote:Any surge suppressor which diverts surges to the ground wire is a Mode 2 suppressor.
<snip>
Unfortunately, this “three mode protection” process diverts high energy powerline surges directly into delicate low voltage audio, video and computer datalines, because these lines use the powerline ground wire circuit for their reference voltage.
Computers with modems or datalines to other equipment, such as LANs and shared printers, should never use Mode 2 surge protectors which divert surges to the powerline ground, because this will increase the likelihood of damage.
A surge which is not diverted by a surge “protector” will hit the computer’s power supply, which is considerably more surge tolerant than the delicate dataline circuitry that Mode 2 suppressors endanger.
(Within the dielectric strength of the insulation, of course.) Granted, non-safety-rated 1kV or 2kV ceramic caps (in non-compliant SMPS) could break down; but I'd never pass a unit containing those, and I don't suppose you would either.Zero Surge wrote:Modern equipment is inherently immune to Common Mode surges.
Well, we have yet to deal too closely with lightning. (No PSUs have yet catastrophically failed here; the only dying supplies have been from bad capacitors.)Behemot wrote:Protection against disasters like lightning is a science of it's own and every protection mechanism you bring in could actually harm you as it brings other problems. You would think that commong quality grounding even between buildings makes sense, right? Well the problem is when you have that and lightning of 1 MV strikes one building: even if you have only 1 ohm resistance on the ground, that makes 100 000 volts induced potential which affect the nearby buildings too. You don't want to touch anything earth grounded when that happens, lol. But equipment-wise, that makes the potential to be 100 kV - 230 V (for us)=pretty much still 100 kV When that happens, no ordinary component will survive such potential difference. But when you have common mode MOVs in there, they will open, allow the current to flow FROM ground to both line/neutral and lower that potential difference. Off course they will blow in an instance, but so will the lightning energy pulse get conducted to the ground too. This is very complicated problem of many transient phenomenons but in the end the MOVs could give some equipment just the few extra microseconds it needs to not break insulation of its components (especially semiconductors).
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