Table 41.1 Assumed Touch Voltage

AJJewsbury:

I suspect it's a mix of history and standardization with a bit of finger in the air approximation thrown in. I believe that 0.4s was agreed on for continental 220V supplies (110V touch voltage if equal sized line/c.p.c.) and we in (then) 240V land adopted the same - arguing that our per-installation bonding would likely reduce the touch voltage inside the building to well below 110V levels. There's a similar argument for permitting reduced c.s.a. c.p.c.s. which otherwise can similarly result in higher touch voltages. Portable equipment outdoors should be covered by a 30mA RCD so have a faster disconnection time anyway.


There are so many unknowns - body resistance, resistance of contact with the general mass of the earth, actual supply voltage, droop in supply voltage due to the short circuit that occurs during a L-PE fault on a TN system, exact effect of main bonding, not to mention variation between individuals - that it's far from being an exact science. There's likely some approximation gone into that table above - nice round whole numbers seem rather unlikely for real life.


   - Andy.

I'd say so by the looks of it. 


The thing is I'd assume worse case scenerios would be observed which IMO are both reasonable and predictable. For example, faults on 32 amp and under circuits are not likely to cause much if any voltage droop on the output of the DNO transformer (16 x 7= 112 amps on a 500kva unit where 700 amps per phase is norm), +105-110% voltage is within bounds, the majority of the voltage division is among the final circuit whereby the few voltages drop across the incoming PEN make little difference in contact voltage when the PEN is bonded to all exposed metal, contact with remote earth is not unreasonable if outside, ect.


However, I do agree with you on body resistance and footwear as it can range dramatically. But considering children, the elderly, ect assuming a 5% of the population number I think is fair.       



 


 

AJJewsbury:

I suspect it's a mix of history and standardization with a bit of finger in the air approximation thrown in. I believe that 0.4s was agreed on for continental 220V supplies (110V touch voltage if equal sized line/c.p.c.) and we in (then) 240V land adopted the same - arguing that our per-installation bonding would likely reduce the touch voltage inside the building to well below 110V levels. There's a similar argument for permitting reduced c.s.a. c.p.c.s. which otherwise can similarly result in higher touch voltages. Portable equipment outdoors should be covered by a 30mA RCD so have a faster disconnection time anyway.


There are so many unknowns - body resistance, resistance of contact with the general mass of the earth, actual supply voltage, droop in supply voltage due to the short circuit that occurs during a L-PE fault on a TN system, exact effect of main bonding, not to mention variation between individuals - that it's far from being an exact science. There's likely some approximation gone into that table above - nice round whole numbers seem rather unlikely for real life.


   - Andy.

I'd say so by the looks of it. 


The thing is I'd assume worse case scenerios would be observed which IMO are both reasonable and predictable. For example, faults on 32 amp and under circuits are not likely to cause much if any voltage droop on the output of the DNO transformer (16 x 7= 112 amps on a 500kva unit where 700 amps per phase is norm), +105-110% voltage is within bounds, the majority of the voltage division is among the final circuit whereby the few voltages drop across the incoming PEN make little difference in contact voltage when the PEN is bonded to all exposed metal, contact with remote earth is not unreasonable if outside, ect.


However, I do agree with you on body resistance and footwear as it can range dramatically. But considering children, the elderly, ect assuming a 5% of the population number I think is fair.