Another change in AMD2 - 551.7.2 - embedded parallel generation

Have a look at 722.551.7.2 ... effectively means the PV has its own circuit so the final circuit provision of 551.7.2 are not applicable.

It's not the 'final circuit' provisions of 551.7.2 I'm worried about, so much as the new 'Where the generating set is connected via a low voltage switchgear...' bit - which as I read it applies regardless of whether the generator circuit is deemed to be a final circuit or a distribution circuit.

At it's most simple, fuses work by getting hot. MCB's and RCBOs also have an element inside that gets hot.

Now that's a very interesting point. I wonder how we're meant to cope with that in SSEG situations where both the DNO fuse and CU rating are often 100A - can't fuse down the mains side without losing available supply capacity so perhaps have the generator OPDs in a separate enclosure and hard-wire the connection to the main CU?

I'm curious to how much of a problem it is likely to be in reality - in some areas (e.g. Ireland) it's common to have either a HBC fuse or a DP MCB as the incoming device - which would effectively double the heat generation from thermal elements within the enclosure (e.g. 126A "hot" for a 63A incomer and the same 63A then going through the outgoing devices) - yet the overall construction seems pretty similar to our CUs with a plain switch disconnector as incomer.

   - Andy.

Have a look at 722.551.7.2 ... effectively means the PV has its own circuit so the final circuit provision of 551.7.2 are not applicable.

It's not the 'final circuit' provisions of 551.7.2 I'm worried about, so much as the new 'Where the generating set is connected via a low voltage switchgear...' bit - which as I read it applies regardless of whether the generator circuit is deemed to be a final circuit or a distribution circuit.

At it's most simple, fuses work by getting hot. MCB's and RCBOs also have an element inside that gets hot.

Now that's a very interesting point. I wonder how we're meant to cope with that in SSEG situations where both the DNO fuse and CU rating are often 100A - can't fuse down the mains side without losing available supply capacity so perhaps have the generator OPDs in a separate enclosure and hard-wire the connection to the main CU?

I'm curious to how much of a problem it is likely to be in reality - in some areas (e.g. Ireland) it's common to have either a HBC fuse or a DP MCB as the incoming device - which would effectively double the heat generation from thermal elements within the enclosure (e.g. 126A "hot" for a 63A incomer and the same 63A then going through the outgoing devices) - yet the overall construction seems pretty similar to our CUs with a plain switch disconnector as incomer.

   - Andy.

Thinking more about this, if we had true double pole MCBs (so a thermal element in 'N' as well as L), we'd be in the same situation - but I've never heard of having to de-rate a distribution board in such a case (e.g. when used for RLV).

Further more, considering a 100A TPN DB - whose basic design is pretty similar to a 100A CU - with long rows of modular devices right next to each other (if anything worse thermally as the rows are normally arranged vertically rather than horizontally so less scope for heat to convect away from individual devices). By this theory we'd have "300A hot".

Or a dual-tariff CU - we could have two 100A supplies into the same enclosure (typically one 24h and one off-peak for storage heating) - potentially from two different DNO fuses - same basic design yet copes with "200A hot".

Is there really any problem with "116A hot" - except perhaps that the CU manufacturer hasn't thought to write down that it'll be fine?

    - Andy.