Dear IET Technical Team,
I am an IET member (MIET) currently reviewing the earthing scheme for about 5 km AC train 960 VAC tunnel supplied from two substations (each with separate earth electrodes, ≤5 Ω). Both substations are interconnected by two paralle
System Configuration Overview:
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Each substation is equipped with its own earth electrode system designed to achieve a resistance of ≤5 ohms.
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The substations are electrically interconnected via two parallel protective earthing (PE) conductors that run along the full tunnel length (5 km), ensuring both equipotential bonding and redundancy.
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These PE conductors are intended to:
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Interconnect both substation earthing systems,
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Provide a continuous protective earth along the tunnel for all connected equipment (lighting, SCADA, signaling, etc.),
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Bond all exposed conductive parts and metallic structures inside the tunnel.
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I would appreciate the IET’s expert input on the following aspects:
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Is the use of only end-point earthing (via the substations) with continuous PE conductors across 3 km acceptable for a 690V AC system, assuming the conductors are adequately sized and bonding is done at regular intervals?
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Would additional intermediate earthing electrodes or equipotential bonding bars be recommended, especially to mitigate the effects of fault current return path impedance or potential rise under earth fault conditions?
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Are there any best-practice thresholds for voltage drop or rise along PE conductors during fault events in such long LV systems, particularly with respect to maintaining safe touch and step voltages in a tunnel environment?
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Which standards would best guide this setup from the UK or international perspective? (e.g., BS 7671 Section 542, EN 50122-1 for railway applications, IET Code of Practice for Earthing, or IEEE Std 80?)
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