13A Switch fuse spur

Bruno Miguel Pereira said:

Hello, Does anyone know if there are regulations stating that the 13A switch fuse spur can run Continuously at is rated current for long hours? I find this intriguing because, when a spur operates at its maximum rating, it tends to overheat, but i can't find any regulation that explicitly states this isn't allowed.

Not directly ... BUT ...Regulation 433.1 is, I think, where you need to go.

Care is needed regarding how the rating of the wiring system and accessories relates to the rating of products when calculating load currents.

For example, BS EN 60335-1 permits current-using equipment to the standard to use 5 % more power (or current) than the stated rating - meaning a device which is rated 13 A may well use 5 % more load current (13.65 A) at nominal rating plate voltage.

The utilization voltage also varies from between + 10 % (253 V) and - 11 % (204.7 V), using BS 7671 voltage drop maximum of nominal. With linear (resistive) loads, such as heaters, the load current increases with increasing voltage, and with switched-mode power loads the current increases with decreasing voltage to achieve the same power.

What this all means, is that a heating load rated 3 kW at 230 V might actually have a load current up to 15.1 A (or as little as 10.4 A). Similarly, a heating load rated 3 kW at 240 V might have a load current as much as 13.8 A (or as little as 9.6 A).

Regulation 433.1 of BS 7671 states:

Every circuit shall be designed so that a small overload of long duration is unlikely to occur.

So, as we can see, even under normal conditions of temperature, a  BS EN 60335-series product rated 13 A (2990 W) at either 230 V or 240 V perhaps should not be used for long periods from a device protected by a 13 A fuse.

Immersion heaters are often rated 3 kW at 240 V, but have the added problem that, if the connected device is in the same room as the heated cylinder, the ambient temperature will be elevated, and wiring and accessories should be derated accordingly. This is noted in Section 5.3.1 of the IET Commentary on the Wiring Regulations. This is supported by BS 1363 series ... BS 1363-4, for example, has in its stated conditions of use for relevant products (connection units, or "spurs") that the maximum ambient temperature is permitted to get to 40 deg C, BUT that the average ambient temperature over 24 hours is not to exceed 25 deg C.

Overall, where a current-using product has a rating exceeding 2.7 kW at 230 V, the rating of accessories for its connection, and any associated protective devices, should be higher than 13 A, and where elevated temperatures are expected, a much lower rating limit for products is necessary for the 13 A limit.

I would, however, at this point, state that there is nothing to prevent a manufacturer exceeding the requirements of BS 1363, and I am in no way making a statement about the suitability of any and all accessories to BS 1363 series for continuous "rated at 13 A" or "rated at 3 kW" loads ... just considering the "minimum performance" that you might need to achieve a conformant product.

Bruno Miguel Pereira said:

Hello, Does anyone know if there are regulations stating that the 13A switch fuse spur can run Continuously at is rated current for long hours? I find this intriguing because, when a spur operates at its maximum rating, it tends to overheat, but i can't find any regulation that explicitly states this isn't allowed.

Not directly ... BUT ...Regulation 433.1 is, I think, where you need to go.

Care is needed regarding how the rating of the wiring system and accessories relates to the rating of products when calculating load currents.

For example, BS EN 60335-1 permits current-using equipment to the standard to use 5 % more power (or current) than the stated rating - meaning a device which is rated 13 A may well use 5 % more load current (13.65 A) at nominal rating plate voltage.

The utilization voltage also varies from between + 10 % (253 V) and - 11 % (204.7 V), using BS 7671 voltage drop maximum of nominal. With linear (resistive) loads, such as heaters, the load current increases with increasing voltage, and with switched-mode power loads the current increases with decreasing voltage to achieve the same power.

What this all means, is that a heating load rated 3 kW at 230 V might actually have a load current up to 15.1 A (or as little as 10.4 A). Similarly, a heating load rated 3 kW at 240 V might have a load current as much as 13.8 A (or as little as 9.6 A).

Regulation 433.1 of BS 7671 states:

Every circuit shall be designed so that a small overload of long duration is unlikely to occur.

So, as we can see, even under normal conditions of temperature, a  BS EN 60335-series product rated 13 A (2990 W) at either 230 V or 240 V perhaps should not be used for long periods from a device protected by a 13 A fuse.

Immersion heaters are often rated 3 kW at 240 V, but have the added problem that, if the connected device is in the same room as the heated cylinder, the ambient temperature will be elevated, and wiring and accessories should be derated accordingly. This is noted in Section 5.3.1 of the IET Commentary on the Wiring Regulations. This is supported by BS 1363 series ... BS 1363-4, for example, has in its stated conditions of use for relevant products (connection units, or "spurs") that the maximum ambient temperature is permitted to get to 40 deg C, BUT that the average ambient temperature over 24 hours is not to exceed 25 deg C.

Overall, where a current-using product has a rating exceeding 2.7 kW at 230 V, the rating of accessories for its connection, and any associated protective devices, should be higher than 13 A, and where elevated temperatures are expected, a much lower rating limit for products is necessary for the 13 A limit.

I would, however, at this point, state that there is nothing to prevent a manufacturer exceeding the requirements of BS 1363, and I am in no way making a statement about the suitability of any and all accessories to BS 1363 series for continuous "rated at 13 A" or "rated at 3 kW" loads ... just considering the "minimum performance" that you might need to achieve a conformant product.