Electronic – Why does this insulator separate two conductors with equal voltages

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Here goes a view-from-below picture of a 3 kilovolts DC railway catenary

http://fotki.yandex.ru/users/poduruev-petr/view/651405/?page=2

Here B is a suspension cable, C is a two-stranded contact wire – one which the train pantograph touches. Between B and C there's a thick jumper cable that is attached to both B and C. Such jumpers are installed every several dozen meters. Also not shown in the picture but there're hundreds of pieces of thin of wire located every several meters that are attached to the suspension cable, hang down to the contact wire and hold the contact wire at exactly the right height above the rails.

So a lot of effort is made to ensure that B and C have equal voltages at all times.

Now A is a cable that comes from a distribution cable running along the railway. The picture shows how that cable "feeds" energy into the contact wire. Such "feed" points occur about every kilometer.

So the "feed" cable A comes from the distribution cable and is connected to the jumper that is in turn connected to both the suspension cable and the contact wire. Clearly A, B and C will have the same voltage on them.

Finally there's that huge insulator. It separates A from B but both A and B have the same voltage so they could have been connected directly without any kind of insulator.

What's the use of that insulator?

Best Answer

It is an insulator so that current does NOT flow through the mechanical link. The mechanical link is not designed to handle high current flows, and may fail if subjected to high current flows.

In a fault condition, you do NOT want to have your mechanical supports fail because they have high current flowing through them.

In non-fault conditions you still don't want to have current flowing through your mechanical supports: they would find an equilibrium where the small fraction of the current flowing through the steel would keep it hot enough to not conduct more current. The hot steel would be susceptible to corrosion, and the threaded connectors would be susceptible to creep.

Note that the voltage is irrelevent for this mechanical support. The insulator is there because, even at 3KV, trains take a lot of current out of the supply. You can get the same problems with Low Voltage (48V) supply systems.