Signal passed at danger

Two-aspect signal at danger

A signal passed at danger (SPAD), in British railway terminology, occurs when a train passes a stop signal without authority to do so.[1] It is a term primarily used within the British railway industry, although it is also used in some other countries.

Categories of SPAD

From December 2012,[2] the term "SPAD" only applies to category A SPADS. A new term, SPAR - Signal Passed at Red, will be used when describing category B, C and D incidents. There are a number of ways that a train can pass a signal at danger, and in the UK these fall into four basic categories:

Causes

As it takes a considerable distance to bring a train to a standstill, many SPADs occur at low speed where the driver has applied the brakes too late. Very often this occurs when the signal at danger cannot be clearly discerned until close up. It can also be due to:

In some situations, however, the driver is unaware that they have passed a signal at danger and so continues until a collision occurs, as in the Ladbroke Grove rail crash. In this instance, it is up to the safety system (where fitted) to apply the brakes, or for the signaller to alert the driver.

Prevention

Automatic Train Protection

ATP (Automatic Train Protection) is a much more advanced form of Train Stop, which can regulate the speed of trains in many more situations other than at a stop signal. ATP supervises speed restrictions and distance to danger points. An ATP does take into account individual train characteristics such as brake performance. Thus, the ATP determines when brakes should be applied in order to stop the train before getting beyond the danger point. In the UK, only a small percentage of trains (First Great Western and Chiltern Railways) are fitted with this equipment.

Driver's Reminder Appliance

The DRA is an inhibiting switch designed specifically to prevent 'Starting Away SPADs' by passenger trains. The driver is required to operate the DRA switch whenever the train is brought to a stand, either[3]

Once applied, the DRA displays a red light, and prevents Traction power from being taken.

Collision avoidance

Whilst the ideal safety system would prevent a SPAD from occurring, most equipment in current use does not stop the train before it has passed the Danger signal. However, provided that the train stops within the designated overlap beyond that signal, a collision should not occur.

Train Detection

There are two main forms of train detection. Track circuits which detect the presence of trains and can, for example, hold signals at stop in the first place to prevent accidents. There is also axle counters which like track circuits, additionally count how many axles of a train has come in and out of the track in order to fully ensure no train is present. All other safety system such as train stops rely on detection systems such as track circuits and axle counters. Additionally a treadle is sometimes used.

Train stops

Main article: Train stop

On the London Underground (for example), train stops are fitted on the track to stop a train, should a SPAD occur. When a train is stopped under such circumstances, delays occur because the train's trip cock has to be reset, and a replacement needs to be found as the driver is not permitted to continue with the train.

Train stops (and trip cock equipped trains) are also operated by the main line railways in places where extensive tunnel operation is carried out, such as the Northern City Line where the Automatic warning system and Train Protection & Warning System are not fitted.

Train Protection & Warning System

On the UK mainline, TPWS consists of an on-board receiver/timer connected to the emergency braking system of a train, and radio frequency transmitter loops located on the track. The 'Overspeed Sensor System' pair of loops is located on the approach to the signal, and will trigger the train brakes if it approaches faster than the 'set speed' when the signal is at danger. The 'Train Stop System' pair of loops is located at the signal, and will trigger the brakes if the train passes over them at any speed when the signal is at danger.

TPWS has proved to be an effective system in the UK, and has prevented several significant collisions. However, its deployment is not universal; only those signals where the risk of collision is considered to be significant are fitted with it.

Flank protection

At certain junctions, especially where if the signal protecting the junction was passed at danger a side collision is likely to result, then flank protection[4] may be used. Derailers and/or facing points beyond the signal protecting the junction will be set in such a position to allow a safe overlap if the signal was passed without authority. This effectively removes the chance of a side-impact collision as the train would be diverted in a parallel path to the approaching train.

SPAD indicators

SPAD indicator

Prior to the introduction of TPWS in the UK, "SPAD indicators" were introduced at 'high risk' locations (for example: the entry to a single track section of line). These SPAD indicators are placed beyond the protecting stop signal and are normally unlit. Should a driver pass the signal at 'danger', some form of train detection, detects this and causes the SPAD indicator to flash red lights to warn the driver of the error. Whenever a SPAD indicator activates, all drivers who observe it are required to stop immediately, even if they can see that the signal pertaining to their own train is showing a proceed aspect. Since the introduction of TPWS, provision of new SPAD indicators has become less common.

Passing signals at danger - with authority

Signals form part of a complex system, and it is inevitable that faults may occur. They are designed to fail safe, so that when problems occur, the affected signal indicates danger (an example where this did not happen was the Clapham Junction rail crash due primarily to faulty wiring). To keep the network running, safety rules enable trains to pass signals that cannot be cleared to a proceed aspect. Provided that authority for the movement is obtained, a SPAD does not occur. Basically, there are two types of signal, and they are treated differently:

Accidents involving SPADs

This list is incomplete; you can help by expanding it.

Accidents involving stop and proceed

(In a stop and proceed accident, a train stops for, then passes, a stop signal according to the rules, but fails to keep to a low speed prepared to stop short of any obstruction)

See also

References

External links

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