ritish plugs include fuses, a built-in ground terminal and yank protection, which are found almost nowhere else in

the world. One particularly innovative part of the design is that the ground terminal is five millimetres longer than the live and neutral terminals. The ground makes contact first, which provides an escape route for any excess charge as the live and neutral contacts mate a moment later. The practical upshot of this is that British plugs are far less likely to arc when connected or disconnected. Connecting and disconnecting powered connections like

this is known as hot disconnecting in industry and, while avoiding arcing is beneficial for safety in the home, in industry the risks are far higher. The first question is — why hot disconnect at all? If

equipment is powered down before disconnecting, all the associated problems can be avoided. For small industrial applications this is acceptable, but as factories expand this solution becomes impractical. Powering down equipment can lead to major losses in production and can be a very time consuming and labour-intensive process to plan and implement. Many industries work this way, and the only real

consequence is a reduction in the connector’s cycle lifetimes as the arcs slam into the contacts over and over. This arcing can lower cycle ratings by over 500 times, so it is certainly a factor to keep in mind, but the increased cost of replacing connectors 500 times more frequently are massively outweighed by the increased production generated by keeping equipment powered up. Another contributing factor is that industrial voltages are often many times larger than the 230 volts of home circuits.

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The possibility of arcing is a direct function of the voltage and the distance between the contacts, so a larger voltage makes for stronger and longer arcs. Because the contacts start off touching, some arcing is

unavoidable at the point they un-mate. This is limited in connectors which include a longer grounding terminal, just like the standard British plug, but arcing will always occur to some degree. However, there are some industrial situations

where even minor arcing poses danger, most notably explosive environments. The threat of catastrophic explosive consequences for

arcing in these environments means that ATEX certified hot-disconnect connectors require an additional design consideration. These connectors, like the Trolex Falcon25, use a two-stage connecting process. First the enclosure mates, and then the live contacts. This

creates an explosion-containing capsule, meaning that if there is an explosive atmosphere present to be ignited by the arc, any explosion is safely contained within the capsule and therefore does not have the opportunity to spread. Hot disconnecting equipment is something that almost

every industry does, but how many plant managers keep the connectors in mind when they do so? A hot disconnect in your home probably feels natural and does not have any negative consequences if you are using an ultra-safe British plug. But, in a factory, it will reduce connector lifespan. However, sacrificing connectors for productivity is a sensible trade off, just one you should understand before you make.


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