EICR C3 mixed manufacturer breakers

I avoid C3's like the plague

Personally this always gets a C1 from me for the simple reason that PFC will always be greater than zero kA and the only rating I can apply to the enclosures and devices is zero kA

AJJewsbury:

I avoid C3's like the plague

Personally this always gets a C1 from me for the simple reason that PFC will always be greater than zero kA and the only rating I can apply to the enclosures and devices is zero kA

I'm a little puzzled... for me:


C1 = actual danger present now (with no additional faults) - e.g. bare line conductors, easily touched.

C2 = danger would be present if a single fault occurred in the future - e.g. broken c.p.c. or Zs too high.

C3 = danger would be present if two faults occurred (and the current regulations provide some protection under those circumstances) - e.g. lack of additional protection.

no code (old code 4) for things that although don't comply with the current regulations pose no additional hazard to users of the installation - e.g. old (or incorrect) core colour codes.


and then following the same weightings as it were for hazards other than shock. So say for example, lack of overload protection but no evidence that anything actually has ever been overloaded might be a C2, evidence that insulation had been melting a C1.


So for me a CU with an inadequate fault breaking capacity would be perfectly safe under the current conditions - any problems would only arise on the future occurrence of a future fault - so that couldn't be higher than a C2 for me.


Likewise C3 seem ideal to me for things like lack of 30mA RCD protection to internal sockets etc.


  - Andy.

 

davezawadi:

Reasonable codes are a requirement for a "qualified" inspector, with "experience" of risk at the correct level. Anything else is simply fraudulent for presumably pecuniary reasons against the unsuspecting and unknowing customer. If I came across an EICR with this coded as C1 I would contact the certifying body, because it is totally unreasonable.


Only 1 answer so far to my questions, negative.

I would argue that a fault has already occured by dint of the assembly having insufficient fault rating for the installation.

Err no. The fault has only occurred when you are called out to take a look at the smoking remains and twisted metal hanging off the wall... 

It could however certainly be C2 - if the next big fault that comes along that should operate ADS, instead blows the thing to bits.

So single fault to danger, not already dangerous.




Like others I can count on the fingers of one foot the no. of times I have ever seen an MCB fail catastrophically  in anything other than film taken during a lab test set up.


The Americans estimate the energy density  from arc events  using these formulae  . I am aware that in the UK we do not normally, but in the US they calculate a rating in joules per cm2 for exposure, and then assume the energy spreads out from the source, to get a safety distance.

However, work beckons,  and I'm having "fun" with the formulae in the forum software , so rather than cock it up I will come back and do it properly in another post, probably tonight.


However, even for an open arc, at the risk of spoiling the conclusion, so long as the arc is cut suitably short by a suitable up stream fuse, you do not need much weight in the way of containment until >>10kA  at mains voltages (less for an arc partly dissipated in tearing up the case of a breaker.) You could probably make a safe CU out of plastic.  ?

'I'm not sufficiently technically competent to override two standards aimed soley at the protection of people