Signal passed at danger

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Two-aspect signal at danger (stop) in the United Kingdom

A signal passed at danger (SPAD)[1]: 75  is an event on a railway where a train passes a stop signal without authority.[2] This is also known as running a red, in the United States as a stop signal overrun (SSO)[3] and in Canada as passing a stop signal.[4] SPAD is defined by Directive 2014/88/EU as any occasion when any part of a train proceeds beyond its authorised movement.[5] Unauthorised movement means to pass:[5]

  • a trackside colour light signal or semaphore at danger, or an order to STOP where a Train Protection system (TPS) is not operational,
  • the end of a safety related movement authority provided in a TPS,
  • a point communicated by verbal or written authorisation laid down in regulations,
  • stop boards (buffer stops are not included) or hand signals.

Etymology

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The name derives from red colour light signals and horizontal semaphore signals in the United Kingdom, which are said to be at danger when they indicate that trains must stop (also known as the signal being on). This terminology is not used in North America where not all red signals indicate stop.[1]: 72  In the UK, a signal passed at red (SPAR) is used where a signal changes to red directly in front of a train, due to a fault or emergency, meaning it is impossible to stop before the signal.

Causes

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The high inertia of trains, and the low adhesion between the wheels and track, means it takes a long distance for the train brakes to stop a train. SPADs are most commonly a small overrun of the signal (instead of a long overrun), because the driver has braked too late. The safety consequences for these types of SPADs may be minor. On the other hand, some SPADs involve the driver being unaware they have passed a signal at danger and continue until notified by network controllers, or a collision occurs, as in the Ladbroke Grove rail crash.

The causes and prevention of SPADs is actively researched. Causes of SPADs are always multidimensional.[citation needed] Some of the causes of SPADs are:

Prevention

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Automatic train protection

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Automatic train protection (ATP) is an advanced form of train stop which can regulate the speed of trains in situations other than at a signal set at danger. ATP can supervise speed restrictions and distance to danger points. It can also take into account individual train characteristics such as brake performance etc. Therefore ATP can determine when brakes should be applied in order to stop the train before passing a signal at danger. Presently, In the UK, only a small percentage of trains (Great Western Railway and Chiltern Railways) are fitted with this equipment.

Driver's reminder appliance

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The driver's reminder appliance (DRA) is an inhibiting switch located on the driver's desk of United Kingdom passenger trains designed specifically to prevent "starting away SPADs". The driver is required to operate the DRA whenever the train is brought to a stand,[10] either after passing a signal displaying caution or at a signal displaying danger.

Once applied, the DRA displays a red light and prevents traction power from being taken until the DRA is manually cancelled by the driver.

Collision prevention systems

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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 stops

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On the London Underground (for example), mechanical train stops are fitted beside the track at signals to stop a train, should an S.P.A.D occur.

Train stops are also installed on main line railways in places where tripcock equipped trains run in extensive tunnels, such as the on the Northern City Line where the Automatic warning system and Train Protection & Warning System are not fitted.

Automatic Warning System

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On the UK mainline, AWS consists of an on-board receiver/timer connected to the emergency braking system of a train, and magnets located in the center of the track. At each AWS site, a permanent magnet arms the system and an electromagnet connected to the green signal lamp disarms the system and a confirming chime is provided to the driver. If the receiver does not disarm within one second after arming, a warning tone sounds at the driver's desk and if it is not cancelled by the driver, the emergency brakes will be activated. A visual indication remains set to remind the driver that they have passed a restrictive signal aspect.

Train Protection & Warning System

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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 activate the train's emergency brake if it approaches faster than the 'trigger speed' when the signal is at danger. The 'Train Stop System' pair of loops is located at the signal, and will activate the emergency brake 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,[citation needed] and has prevented several significant collisions.[citation needed] 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

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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[11] 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

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SPAD indicator
Animation demonstrating a SPAD indicator in action.
Animation demonstrating a SPAD indicator in action.

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). Consisting of three red lamps, they are placed beyond the protecting stop signal and are normally unlit. If a driver passes the signal at 'danger', the top and bottom lamps flash red and the centre lamp, which has the word "STOP" written across the lens in black, is lit continuously. 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.

UK acronyms: SPAD / SPAR

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In the UK, incidents where a signal is passed at danger without authority are categorised according to principal cause. A SPAD is where the train proceeds beyond its authorised movement to an unauthorised movement. Other types are categorised as SPAR ("signal passed at red").

Prior to December 2012,[12] the term "SPAD" applied to all such incidents, with a letter specifying cause.

  • A SPAD (formerly Category A SPAD) is where the train proceeds beyond its authorised movement to an unauthorised movement.[12]
  • A Technical SPAR (formerly Category B SPAD) is where the signal reverted to danger in front of the train due to an equipment failure or signaller error and the train was unable to stop before passing the signal.
  • A Signaller SPAR (formerly Category C SPAD) is where the signal was replaced to danger in front of the train by the signaller in accordance with the rules and regulations and the train was unable to stop before passing the signal.
  • A Runaway SPAR (formerly Category D SPAD) is where an unattended train or vehicles not attached to a traction unit run away past a signal at danger. Note that where this was the fault of the driver, this will be classed as a SPAD.

Some SPADs are defined as a;

  • SAS SPAD – "Starting against signal" SPAD,[13] where the train was standing at a danger signal and the driver moved past it.
  • SOY SPAD – "Starting on yellow" SPAD,[13] where the train started on a caution signal and the driver did not appreciate that the next signal would be at danger.

Passing signals at danger – with authority

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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, known as a wrong-side failure, 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. There are two methods of obtaining that authority:[14]

Driver obtains signaller's authority to pass a signal at danger

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Once the train has been brought to a stand at a signal which is at danger, the driver should attempt to contact the signaller. If the signal cannot be cleared then the driver must obtain the signaller's authority to pass it at danger. Methods for contacting the signaller may include GSM-R cab radio, signal post telephone or mobile phone.

The signaller can authorise a driver to pass a signal at danger when:[15]

  • The signal is defective or disconnected
  • The signal cannot be cleared because signalling or level crossing equipment has failed
  • The signal is to be passed at danger for shunting purposes
  • The signal cannot be cleared because a train or movement which has reversed is then required to start from beyond that signal
  • An electric train is to pass the signal protecting an isolated section and proceed towards the limiting point
  • A train has been accepted using restricted acceptance because the line is clear only up to the home signal of the next signal box and the section signal cannot be cleared
  • In an emergency, and then only when authorised by the signal box supervisor or Operations Control, so that a train carrying passengers can enter an occupied section to use a station platform
  • An engineering train is to move towards a possession, or leave a line under possession at an intermediate point
  • A train is to pass the signal protecting engineering work to gain access to a station where the train is required to start back, or a line under single line working, or a siding
  • The line is to be examined to check that it is clear
  • A train is to proceed at caution through an absolute block section from the signal box in rear when a failed train has been removed
  • A train is to enter the section after a train or vehicle that has proceeded without authority has been removed, or the front portion of a divided train has passed through the section
  • A train is to enter the section to assist a failed train, evacuate passengers from a failed train, remove a portion of a divided train, or remove a train or vehicles that have proceeded without authority
  • Single line working applies
  • Working by pilotman or modified working applies

The driver and signaller must come to a clear understanding, and ensure they agree about how it is to be done. In the UK the signaller tells the driver of a specific train to pass a specific signal at danger, proceed with caution and travel at a speed that enables him to stop short of any obstruction, and then obey all other signals. If the signal is fitted with TPWS, the driver resets the Driver Reminder Appliance, pushes the TPWS Trainstop Override button in the cab, and proceeds cautiously through the section. If the train reaches the next signal without finding an obstruction, they must obey its aspect, at which point they can revert to normal working.

Driver passes a signal at danger under their own authority

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If contact with the signaller cannot be made then the driver must not move the train, unless it is standing at one of the following signals:

  • A signal controlled from a signal box that is closed on absolute block line only.
  • An automatic signal where local instructions permit it, e.g. signals within tunnels on the Northern City Line.

After passing a signal at danger under their own authority, the driver must stop at the next signal (even if it is showing a proceed aspect) and inform the signaller of what they have done.

EU statistics of SPADs as precursors of accidents

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ERADIS database on SPADs as precursors of accidents per million kilometers[16]
Area 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022
Austria 0,099 0,077 0,101 0,131 0,070 0,033 0,067 0,080 0,072 0,255 0,378 0,398 0,553 0,768 0,630 0,848 0,834
Belgium 0,782 1,044 0,816 1,061 0,905 0,756 0,577 0,683 0,952 0,937 0,550 0,739 0,744 0,576 0,752 0,877
Bulgaria 0,139 0,416 0,342 0,095 0,000 0,128 0,144 0,568 0,556 0,431 0,680 0,752 0,605 0,958 0,924 0,701 0,734
Switzerland 0,182 0,561 0,610 0,689 0,599 0,613 0,492 0,457 0,543 0,593 0,574 0,540 0,576 0,712
Channel Tunnel 0,765 0,542 0,708 0,525 1,071 1,042 0,168 0,713 0,374 0,241 0,610 0,606 0,253 0,769 1,302 0,694
Czechia 0,377 0,170 0,149 0,239 0,487 0,529 0,496 0,485 0,525 0,562 0,716 0,763 0,815 0,840 0,886 1,001 0,988
Germany 0,693 0,728 0,354 0,341 0,441 0,385 0,361 0,451 0,463 0,490 0,506 0,566 0,519 0,510 0,577 0,564
Denmark 9,387 1,283 1,378 3,311 2,859 2,664 2,198 2,231 1,833 1,943 1,943 2,292 2,257 2,708 2,390 3,008 3,562
Estonia 0,265 0,280 0,147 0,000 0,143 0,284 0,000 0,534 0,710 0,597 0,768 0,694 0,818 0,606 0,822 0,147
Greece 0,052 0,050 0,047 0,255 0,059 0,239 0,086 0,000 11,259 0,000 0,000 0,000 0,000 0,000
Spain 0,502 0,501 0,576 0,500 0,466 0,408 0,408 0,408 0,406 0,423 0,468 0,577 0,460 0,519 0,498 0,421 0,574
Finland 0,354 0,418 0,563 0,400 0,686 0,392 0,393 0,654 0,604 1,030 1,325 1,268 0,813 0,951 0,534 0,699 0,328
France 0,069 0,212 0,229 0,264 0,231 0,255 0,238 0,293 0,302 0,241 0,304 0,319 0,413 0,537 0,599 0,584 0,466
Croatia 0,000 0,000 0,096 0,048 0,000 0,082 0,092 0,099 0,143 0,095
Hungary 0,075 0,105 0,073 0,066 0,098 0,164 0,202 0,173 0,168 0,101 0,037 0,157 0,083 0,130 0,799 0,204 0,611
Ireland 1,919 1,842 1,104 1,155 0,791 0,332 0,435 0,985 0,547 0,827 0,712 0,480 0,713 0,628 0,643 0,449 0,659
Italy 0,064 0,041 0,055 0,043 0,031 0,038 0,063 0,051 0,064 0,056 0,070 0,085 0,065 0,103 0,098 0,107 0,080
Lithuania 8,968 4,002 0,190 0,498 0,142 0,000 0,273 0,212 0,070 0,212 0,000 0,195 0,065 0,296 0,000 0,203 0,168
Luxembourg 0,124 0,490 1,241 0,571 0,444 0,666 1,633 0,345 1,233 0,805 0,927 0,641 0,856 0,628
Latvia 0,234 0,108 0,256 0,214 0,361 0,108 0,159 0,228 0,158 0,323 0,061 0,192 0,118 0,196 0,259 0,270 0,357
Netherlands 2,195 1,964 1,727 1,621 1,156 1,040 0,007 0,000 0,720 0,642 0,635 0,661 0,842 0,863 0,626 0,657 0,673
Norway 1,646 1,540 1,494 2,426 2,497 1,265 1,091 1,360 1,377 1,179 1,251 1,260 1,367 1,319 1,127 0,937 1,246
Poland 17,993 11,825 0,062 0,059 0,128 0,147 0,157 0,300 0,276 0,320 0,386 0,431 0,410 0,381 0,591 0,552
Portugal 0,611 0,488 0,575 0,296 0,150 0,591 0,667 0,717 0,821 0,444 0,862 0,471 0,522 0,219 0,757 0,783 0,646
Romania 4,478 4,415 4,119 4,881 6,106 4,971 4,122 4,339 3,183 5,344 4,576 3,430 3,752 3,948 0,000 0,000 0,000
Sweden 1,466 1,615 1,990 2,530 2,413 2,116 2,336 2,046 1,678 0,943 1,526 1,746 2,055 1,690 1,441 1,603 1,490
Slovenia 0,790 0,835 0,746 0,659 0,531 0,246 0,302 0,000 0,390 0,325 0,141 0,409 0,000 0,099 0,296 0,000 0,094
Slovakia 1,530 1,549 1,520 1,668 0,463 0,551 0,843 0,706 0,383 0,457 0,492 0,581 0,568 0,394 0,692 0,648 0,492
United Kingdom 0,657 0,622 0,576 0,457 0,585 0,509 0,411 0,498 0,551 0,493 0,419 0,514 0,559 0,573 0,517

Accidents involving a signal passed at danger without authority

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Country Incident Year
United States Norwalk rail accident 1853
United Kingdom Lewisham rail crash 1857
Canada St-Hilaire train disaster 1864
United Kingdom Hexthorpe rail accident 1887
Denmark Gentofte train crash 1897
United Kingdom Potters Bar rail accidents 1898
United Kingdom Slough rail accident 1900
United States Washington DC train wreck 1906
Australia Sunshine rail disaster 1908
United Kingdom Tonbridge accident 1909
United Kingdom Ais Gill disaster 1913
United Kingdom Ilford rail crash 1915
Hungary Herceghalom rail crash 1916
United Kingdom Charfield railway disaster 1928
Germany Genthin rail disaster 1939
United Kingdom Norton Fitzwarren rail crash 1940
United Kingdom Eccles rail crash 1941
United States Lackawanna Limited wreck 1943
United Kingdom Potters Bar rail accidents 1946
United Kingdom Harrow and Wealdstone rail crash 1952
United Kingdom Luton rail crash 1955
United Kingdom Lewisham rail crash 1957
United Kingdom Dagenham East rail crash 1958
United States Newark Bay rail accident 1958
United Kingdom Coppenhall Junction railway accident 1962
Netherlands Harmelen train disaster 1962
United Kingdom Marden rail crash 1969
Australia Violet Town railway disaster 1969
United Kingdom Paisley Gilmour Street rail accident 1979
United Kingdom Invergowrie rail accident 1979
United States Philadelphia Conrail West Chester Branch collision 1979
Poland Otłoczyn railway accident 1980
United Kingdom Wembley Central rail crash 1984
United Kingdom Eccles rail crash 1984
Canada Hinton train collision 1986
United Kingdom Colwich rail crash 1986
United States Chase train collision 1987
United Kingdom Glasgow Bellgrove rail crash 1989
United Kingdom Purley station rail crash 1989
Germany Rüsselsheim train disaster 1990
Japan Shigaraki train disaster 1991
United Kingdom Newton rail accident 1991
United Kingdom Cowden rail crash 1994
Canada Toronto subway accident 1995
Germany Garmisch-Partenkirchen train collision 1995
United States Secaucus Train Collision 1996
United States Silver Spring train collision 1996
Australia Hines Hill train collision 1996
United Kingdom Southall rail crash 1997
Australia Beresfield rail disaster 1997
Finland Suonenjoki rail collision 1998
United Kingdom Spa Road Junction rail crash 1999
United Kingdom Winsford railway accident 1999
United Kingdom Ladbroke Grove rail crash 1999
Norway Åsta accident 2000
Belgium Pécrot 2001
United Kingdom Norton Bridge rail crash 2003
Egypt Qalyoub rail accident 2006
Netherlands Arnhem 2006
United States Chatsworth train collision 2008[17]
Belgium Halle train collision 2010
India Badarwas train collision 2010
Indonesia Petarukan train collision 2010
Germany Saxony-Anhalt train accident 2011
Netherlands Sloterdijk train collision 2012
United States Goodwell, Oklahoma 2012[18]
Switzerland Granges-près-Marnand 2013
Romania Cotești 2014[19]
Belgium Hermalle-sous-Huy train collision 2016
Portugal Soure train crash 2020[20]
United Kingdom Salisbury rail crash 2021[21]

Accidents following a signal passed at danger with authority

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Whenever a signal is passed at danger the driver is required to "proceed with caution, stop short of any obstructions, and drive at speed that will enable you to stop within the distance which you can see to be clear". Failure to do this has caused the following collisions:

Accidents where the signaller incorrectly authorised a driver to pass a signal at danger

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Except where permissive working is in use, interlocking usually prevents a train from being signalled into a section that is already occupied. When operational needs require it, this can be overridden, and provided it is carried out in accordance with the rules this is a safe practice. However, failure to follow protocol can result in a collision:

See also

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  • Ding-ding, and away, British slang for a guard incorrectly giving permission to a driver to start away from a platform against a red signal.

References

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  1. ^ a b "Canadian Rail Operating Rules" (PDF). Transport Canada. 24 April 2020. Retrieved 18 May 2021.
  2. ^ "Signals Passed at Danger". ORR.gov.uk. Office of Rail and Road. Retrieved 12 May 2018.
  3. ^ Multer, Jordan; Safar, Hadar; Roth, Emilie; France, Megan (June 2019). Why do Passenger Trains Pass Stop Signals – A Systems View (PDF) (Report). Washington, DC: Federal Railroad Administration. DOT/FRA/ORD-19/19. Archived (PDF) from the original on 18 May 2021. Retrieved 18 May 2021.
  4. ^ a b Hersman, Deborah. "Texting: Tomorrow's Unacceptable Behavior". National Transportation Safety Board. Archived from the original on 15 February 2017. Retrieved 11 September 2016.
  5. ^ a b "L_2014201EN.01000901.xml". eur-lex.europa.eu. Retrieved 20 September 2024. This article incorporates text from this source, which is available under the CC BY 4.0 license.
  6. ^ a b c "Articles" (PDF).
  7. ^ "Driver fatigue caused two Reading SPADs, says RAIB report". Rail Magazine. Vol. 812. 26 October – 8 November 2016. p. 23.
  8. ^ "Managing the risk from fatigue" (PDF). RSSB. Rail Safety and Standards Board. Retrieved 21 November 2016.
  9. ^ a b c d "Signal DP29 passed at danger involving suburban passenger train DW17 and near collision with another suburban passenger train Park Road Station, Queensland, on 25 March 2019".
  10. ^ "Online Rulebook – Module TW1 – Section 10.3" (PDF). RSSB. Archived from the original (PDF) on 29 September 2011. Retrieved 16 May 2010.
  11. ^ "Railway Group Standards: Provision of Overlaps, Flank Protection & Trapping" (PDF). RGS. Retrieved 18 February 2011.
  12. ^ a b "GO/RT3119 - Accident and Incident Investigation" (PDF). December 2012. Archived from the original (PDF) on 12 November 2013. Retrieved 12 November 2013.
  13. ^ a b "Professional Driving Policy – a Freedom of Information request to East Coast Main Line Company Limited". WhatDoTheyKnow. 27 January 2015.
  14. ^ "Online Rulebook – Module S5 – Section 1.1 "Signaller's authority"" (PDF). RSSB. Archived from the original (PDF) on 29 September 2011. Retrieved 4 March 2016.
  15. ^ "Online Rulebook – Module S5 – Section 1 "When a signal can be passed at danger"" (PDF). RSSB. Archived from the original (PDF) on 29 September 2011. Retrieved 18 June 2017.
  16. ^ "European Railway Agency Database of Interoperability and Safety". European Union Agency for Railways. Retrieved 20 September 2024.
  17. ^ National Transportation Safety Board (21 January 2010). "NTSB determines engineer's failure to observe and respond to red signal caused 2008 Chatsworth accident; recorders in cabs recommended" (Press release). Archived from the original on 10 February 2010. Retrieved 23 January 2010.
  18. ^ National Transportation Safety Board (18 June 2013), NTSB Head-On Collision of Two Union Pacific Railroad Freight Trains Near Goodwell, Oklahoma June 24, 2012 (PDF), retrieved 24 November 2013
  19. ^ Clock, Nine O' (4 August 2014). "Rail accident at entry point of Cotesti station of the Galati Regional".
  20. ^ Neves, Sofia (1 August 2020). "Erro humano causou acidente com Alfa Pendular em Soure. Operadores da máquina passaram o sinal vermelho" [Human error caused Alfa Pendular crash in Soure. [Maintenance] vehicle drivers passed signal at danger]. Público (in Portuguese). Retrieved 13 April 2021.
  21. ^ "Collision between passenger trains at Salisbury Tunnel Junction". GOV.UK. Retrieved 3 November 2021.
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