Pierre I have a little more time for this now.
There are only two types of transient events that have already been discussed; Normal mode (aka differential modes), and common mode. There are no others.
According to IEEE and the NLSI 95% of all transients experienced in home and businesses is ?Normal Mode? because they happen on the primary side of the utility transformer. So for a service entrance device all you need is protectors from L-L and L-N. Even if there were some way (like lightning striking your overhead service conductor) for a common mode event to happen, it is a waste of material to have common mode protection at a service entrance from L-G and N-G because of what requirement in the NEC? 250.24 maybe?
So here is what manufactures wrestle with when designing series rated equipment, it?s the same dilemma I wrestled with when collaborating designs with ACT (now known as GE). A ?series TVSS? used at the service entrance would have to be designed and tested as service entrance rated equipment fully capable of withstanding full load and fault currents. I hope you see the problem with that approach. Can you imagine all the configurations a manufacture would have to come up with, and how much money would be involved in listing each and every configuration? Well the simple answer is it is impractical.
The next best approach is what a lot of manufactures now offer is standard ?parallel protection built into the switch gear or main panels. The one I really like for 200-amp or less services is the meter collar type.
So when a parallel unit operates at the service entrance 1 of 3 things is noticed beyond that point:
1. Nothing
2. Brown-out because the event was large enough for the SAD?s, MOV?s, Tubes or whatever clamped long enough with a low enough impedance it briefly short out the service lowering the voltage temporarily before returning to normal operation.
3. Black out because the TVSS dropped the transformer service fuse or some other OCPD upstream.
Now for common mode, parallel units work the exact same way by clamping or lowering the internal impedance. So is it fair to say it dumps the event to ground? The answer is both yes and no. Yes from the perspective a short appears between L-G or N-G, so there is fault current flowing, but what is the impedance of the ground circuit at the frequency of the event like lightning? Well I am not going to cover the math again, but needless to say the ground circuit impedance at lightning frequencies is enormous.
OK, one example: The impedance of a single 10-foot long 750 MCM GEC is more than 3K-ohms. So what is the impedance of an EGC in series with the GEC? I don?t know or care, it is useless in this event.
Now that doesn?t mean we can?t have something useful at the point of use, we just have to design something that work using parallel devices and or series devices. So what is it? What I call a Surge Reference Equalizer, you know what they are, the power strips you use at your computer to plug in all the components for power including I/O ports for all the gizmos.
Inside the black box (Surge Reference Equalizer) is a ground buss and L-N buss. MOV?s are installed in all modes (L-N, L-G, and N-G) on the AC, plus protectors on each I/O port from L-L, and the magic L-G mode. So if an event occurs we now have a faux single point ground formed by the protectors, thereby limiting voltages to acceptable limits in all modes across all devices.
Now we can take that one step further by installing an isolation transformer inside the black box eliminating common mode occurrence on the output side of the transformer. Ever seen one? Lots of them on the market for home entertainment centers. The ultimate device is a true dual conversion UPS.
OK, enough for now.
