Open pen and adjacent ev,s.

When 2 vechiles are simultaneously accessible, ie in a street charging next to each other , will the open pen device ( assuming each charger has one ) operate if for example they are fed via 2 differing supply transformer earths ? .

And do the granny chargers even have open pen devices within them ? 


I’ve been wondering about this , and the kerbo channel system , and the fact you can easily buy granny chargers in 20m lengths now .

was a  topic of conversation on the latest eFIXX video and got me thinking again !

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  • When 2 vechiles are simultaneously accessible, ie in a street charging next to each other , will the open pen device ( assuming each charger has one ) operate if for example they are fed via 2 differing supply transformer earths ? .

    It will if there's an open-PEN fault, but open-PEN is not the big issue here. In fact, it's an issue for any installation where ADS is used ... including TN-S and TT installations that are not affected by PME, as well as TN-C-S.

    A more serious issue is that this arrangement is not conformant to BS 7671. BS 7671 is not guaranteed to protect against shock from simultaneously-accessible exposed-conductive-parts connected to different earthing systems, and is a fundamental requirement for Automatic Disconnection of Supply - see Regulation 411.3.1.1 (highlighted 2nd para):

    411.3.1.1 Protective earthing
    Exposed-conductive-parts shall be connected to a protective conductor under the specific conditions for each type of system earthing as specified in Regulations 411.4 to 411.6.

    Simultaneously accessible exposed-conductive-parts shall be connected to the same earthing system individually, in groups or collectively.

    Conductors for protective earthing shall comply with Chapter 54.

    A circuit protective conductor shall be run to and terminated at each point in wiring and at each accessory except a lampholder having no exposed-conductive-parts and suspended from such a point.

    The need for a Simultaneous Contact Assessment is discussed in Section 3.5 of the IET Code of Practice for EV Charging Equipment Installation.

  • Are Granny chargers generally not equipped with integrated open PEN protection devices? I thought these chargers are commonly utilized as interim solutions pending the installation of a permanent charger.

  • Are Granny chargers generally not equipped with integrated open PEN protection devices?

    No, there are two flavours of "granny charger:

    "Mode 1" which is, sadly, just an extension lead. These won't work with new vehicles, and it's no longer permitted to sell EVs that can use them.

    "Mode 2" has an in-cable control box (ICCB) that incorporates some residual current protection, and N-E monitoring via the "pilot" function between the ICCB and vehicle.

    The ICCB, being international standards, doesn't include an open-PEN device (OPDD) - so if you want to dedicate a socket-outlet to EV charging using Mode 2, you'd have to provide something in the electrical installation to conform to Reg 722.411.4.1

  • Sorry for bringing this post up but I had very similar thoughts to the OP after watching the eFIXX video.

    If we are not worried about the broken PEN scenario (as we would be using open PEN home chargers), then the remaining risk as I understand it is a car becoming live due to an internal fault inducing voltage via an adjacent car being charged or a street furniture.

    But wouldn't the internal fault in the car simply be picked up by the Type B RCD despite the different earthing systems?

  •  then the remaining risk as I understand it is a car becoming live due to an internal fault inducing voltage via an adjacent car being charged or a street furniture.

    When you have two different earthing systems in reach of each other, there's a risk of someone getting a shock when touching both at the same time. The problem is that earthing systems are rarely at exactly true earth potential - in TT systems normal leakage currents can raise the voltage on an earthing system (e.g. 50mA leakage * 500Ω rod yields 25V) and the one next door might similar magnitude but out of phase giving an even greater p.d. between them). TN-C-S systems will have their PE raised by the voltage drop of N currents on the supplier's network. Permitted voltage drop can be 16% of 230V - so around 37V - in worst case conditions half of which could be along the PEN, so raising the consumer's earth by that amount. Even TN-S systems aren't entirely immune as there can be current flowing in the PE conductors even in normal conditions (long term N-PE faults are common on TN systems and if there's no RCD they'll remain undetected). Then on top of that any kind of L-PE fault will drag the voltage on the earthing system up very significantly - and the fault doesn't have to be in the EV or even in the same installation - it could be almost anywhere on the system. L-PE faults within consumer's installations (where BS 7671 applies) could take up 5s to clear (and some older installations perhaps a little longer) but faults on the DNO's networks can take longer (maybe several tens of seconds or even minutes) - and there's no main bonding outdoors to mitigate the effects of faults imported into the installation from elsewhere. Then you can add broken PEN events on top of that. Hence the general concept of not having separate earthing system within reach of each other.

    On the other hand, in practice things are very rarely that bad. Individually TT'd charge points will have limited leakage current and won't be import nasty voltages from elsewhere. In 3-phase TN-C-S distribution systems, N currents tend to cancel out, so much of the time the voltage drop long the PEN will be quite small, and broken PEN events are still pretty rare, so much of the time the earthing system for EVSE (and other things in the vicinity) will be pretty close to zero volts.

    Then look at the regs again - while an earthing system has to be kept out of reach of another earthing system, there's no requirement to keep it out of reach of anything else that happens to be earthy - e.g. extraneous-conductive-parts outdoors or indeed the general mass of the Earth itself. So a certain level of risk is deemed acceptable it seems.

    So, as an observation, as long as the "other" earthing system is pretty close to 0V, the risks even if your earthing system is at an elevated voltage, perhaps isn't any worse that a compliant situation where its accessible simultaneously with the general mass of the earth (or something metallic stuck into it - e.g. a sign post). And the changes of two separate faults affecting two separate earthing systems simultaneously quickly get vanishingly small - e.g. if the change of one fault was as low as 1 in1000, then two simultaneously would be one in a million.

       - Andy.

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  •  then the remaining risk as I understand it is a car becoming live due to an internal fault inducing voltage via an adjacent car being charged or a street furniture.

    When you have two different earthing systems in reach of each other, there's a risk of someone getting a shock when touching both at the same time. The problem is that earthing systems are rarely at exactly true earth potential - in TT systems normal leakage currents can raise the voltage on an earthing system (e.g. 50mA leakage * 500Ω rod yields 25V) and the one next door might similar magnitude but out of phase giving an even greater p.d. between them). TN-C-S systems will have their PE raised by the voltage drop of N currents on the supplier's network. Permitted voltage drop can be 16% of 230V - so around 37V - in worst case conditions half of which could be along the PEN, so raising the consumer's earth by that amount. Even TN-S systems aren't entirely immune as there can be current flowing in the PE conductors even in normal conditions (long term N-PE faults are common on TN systems and if there's no RCD they'll remain undetected). Then on top of that any kind of L-PE fault will drag the voltage on the earthing system up very significantly - and the fault doesn't have to be in the EV or even in the same installation - it could be almost anywhere on the system. L-PE faults within consumer's installations (where BS 7671 applies) could take up 5s to clear (and some older installations perhaps a little longer) but faults on the DNO's networks can take longer (maybe several tens of seconds or even minutes) - and there's no main bonding outdoors to mitigate the effects of faults imported into the installation from elsewhere. Then you can add broken PEN events on top of that. Hence the general concept of not having separate earthing system within reach of each other.

    On the other hand, in practice things are very rarely that bad. Individually TT'd charge points will have limited leakage current and won't be import nasty voltages from elsewhere. In 3-phase TN-C-S distribution systems, N currents tend to cancel out, so much of the time the voltage drop long the PEN will be quite small, and broken PEN events are still pretty rare, so much of the time the earthing system for EVSE (and other things in the vicinity) will be pretty close to zero volts.

    Then look at the regs again - while an earthing system has to be kept out of reach of another earthing system, there's no requirement to keep it out of reach of anything else that happens to be earthy - e.g. extraneous-conductive-parts outdoors or indeed the general mass of the Earth itself. So a certain level of risk is deemed acceptable it seems.

    So, as an observation, as long as the "other" earthing system is pretty close to 0V, the risks even if your earthing system is at an elevated voltage, perhaps isn't any worse that a compliant situation where its accessible simultaneously with the general mass of the earth (or something metallic stuck into it - e.g. a sign post). And the changes of two separate faults affecting two separate earthing systems simultaneously quickly get vanishingly small - e.g. if the change of one fault was as low as 1 in1000, then two simultaneously would be one in a million.

       - Andy.

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