Touch voltage

Hello

I have a basic question on touch voltage. I just can't seem to grasp it..
This is taken from guidance note 5
I have attached 3 sketches alongside .

1 and 2 are as GN5 describes

The third is my confusion.

1 & 2. We calculated touch voltage, in this case 126V without MPB and 94V with MPB

Now I understand I think the basic concept the greater the resistance , the higher the voltage current being constant

Number 3, is How I imagine it...
We have a fault and at the Exposed CP we have a voltage of say 115V
The resistance of the CPC to the MET will reduce this voltage again to say half again so 57.5V at the MET

Since we have MPB connected to the MET . The MET and Extraneous part will be  roughly at 57.5V

So our touch voltage would be between the EXP and EXT conductive part so.115V   ----   57.5V   A difference of  57.5V

I don't understand in the GN5 examples, Why is  touch voltage is one amount?
126 volts to what?  To Earth? 
But since the MET will be at a raised potential It can't be to earth?

Hope that makes sense.


Parents
  • The touch voltage calculated assumes the person subject to it is standing on a floor that is remote from earth, as would be the case inside most normal buildings. The value is the product of the fault current and the resistance of that part of the earth path from the fault to the DNO transformer when no main protective is in place or just the voltage drop along R2 when it is in place. In TN systems with low values of resistance in the earth path back to the transformer, the effect of main protective bonding will be relatively small in reducing touch voltage, but is crucial in TT systems where without MPB, the touch voltage could be close to the full fat system voltage to earth.



Reply
  • The touch voltage calculated assumes the person subject to it is standing on a floor that is remote from earth, as would be the case inside most normal buildings. The value is the product of the fault current and the resistance of that part of the earth path from the fault to the DNO transformer when no main protective is in place or just the voltage drop along R2 when it is in place. In TN systems with low values of resistance in the earth path back to the transformer, the effect of main protective bonding will be relatively small in reducing touch voltage, but is crucial in TT systems where without MPB, the touch voltage could be close to the full fat system voltage to earth.



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