The problem is that the voltage gradient will still exist, even with a local grounding electrode. At about 3' from the electrode you will have 85% of the voltage that is on the item being grounded. The only way to get rid of this voltage is by bonding back to the source so the OCPD will clear the fault.
Well, given this, then you understand my point, but just don't realize yet that you agree with it. If you have 85% voltage (15% difference) at 3-feet, then you have not killed your dog, whose stride is only 18 to 24 inches.
If you have done "hot work", then you know that you can touch an elevated voltage as long as you don't simultaneously touch a non-elevated voltage. What killed the dog was that he had 100% voltage gradient (for example only) within his stride. If you have 85% voltage at a radius of 3 feet, then you have only 15% voltage difference across this distance. In some cases, possibly this one, that is the difference between being lethal and an irritating tingle.
In the non-grounded scenario, you will have 100% voltage difference across mere inches. In the grounded scenario, you will spread this voltage difference out across several feet--depending on the conductivity of the soil.
The farther you spread this voltage gradient, the less lethal it will be, simply by preventing a person's body from being capable of spanning 100% of the entire gradient.
Consider the example of a nearby (not direct) lightning strike. During a nearby lightning strike, the person with their feet close together will survive, while the person with a wide stance will be killed. That's because the close feet position will have a lesser voltage difference than the wider foot stance.
If you are having a hard time believing that a voltage can exist without a direct fault, put an ammeter on your grounding conductor downstream from the bonding location. If your system has no faults or improper ground loops, then you should never see current at this location. But the fact is, it is common to have current on the grounding conductor downstream from the bond. Current doesn't flow without a voltage difference driving it.
With a utility supplied system there are multiple points where the system is connected to the earth. There will always be some current on the Grounding Electrode Conductor because there is a parallel path, via the grounding electrode and the earth, for the grounded conductor current. The voltage that drives this current is the voltage drop on the service grounded conductor.
Re-read what I said more carefully. I stated "downstream from the main bonding point". What you are describing is the result of multiple ground loops created as the result of how the POCO installs their system.
Downstream from the main bonding point, there should not be any ground loops, and therefore, there should be zero current on the grounding conductor (by your assertion, not mine) unless there is a fault.
In reality, there is current on that conductor (conductors) because there will be induced voltages within the system that are not attributed to direct faults.
. But as long as the electrical workers that fix it know what's going on and understand the difference between grounding and bonding and so forth, then I'm satisfied with that.
