A rail operating centre (ROC) is a building that houses all signallers, signalling equipment, ancillaries and operators for a specific region or route on the United Kingdom's main rail network. The ROC supplants the work of several other signal boxes which have thus become redundant.
Network Rail announced the creation of fourteen[1] [2] ROCs situated throughout Great Britain that will control all railway signalling over the British National Rail network. This was subsequently revised to twelve ROCs[3] with responsibilities at two (Saltley and Ashford) being transferred to other ROCs (Rugby and Gillingham respectively).
In November 2016, Network Rail announced that the ROC at Edinburgh would not go into operation with all its functions and responsibilities being transferred to Cowlairs in Glasgow.[4]
Nationally this has meant the redundancy of eight hundred mechanical-lever signal boxes[5] and around two hundred panel and IECC boxes.[6] Some are listed buildings and will be left in situ.[7]
The ROCs are built under private contracts for Network Rail, and will only control the rail routes controlled by Network Rail. Railways in Northern Ireland, various heritage railways and other tramways are not subject to control by a ROC. Ashford IECC still controls the UK stretch of the Channel Tunnel Rail Link (HS1/CTRL), which is owned by London and Continental Railways and not Network Rail.
The ROCs function as signalling and control centres with signalling staff, train operating company (TOC) staff and Network Rail controllers all working under one roof. This is meant to enable quick solutions to signalling problems and fewer delays to trains and passengers. Network Rail envisage the twelve ROCs to be controlling the entire network by 2058.[8]
See main article: UK railway signalling.
Originally, the early railways employed 'policemen' to time the intervals between trains and to give a 'stop' signal if a train had passed in the previous ten minutes.[9] Developments led to many everyday workings (such as interlocking points)[10] and signal boxes to house the levers that allowed signallers to change the points and signals over a given stretch of railway.[11] These signalboxes were often elevated above the railway due to the locking mechanisms of the signals and points being accommodated on the lower storey.[12] This also allowed the signaller to keep an eye on things from a good vantage point.[13]
At the end of the Second World War, the United Kingdom network was host to over ten thousand mechanical-lever signalboxes.[14] When British Rail was created from the Big Four private railway companies[15] [16] under the Transport Act 1947,[17] they began to install power signal boxes (PSB) at strategic locations such as Euston, Crewe, Doncaster, Rugby and Carlisle.[18] The PSBs would remove the necessity for many individual boxes along a particular route and would pass control to one centralized location. Carlisle's PSB took over the responsibility of 44 signal boxes alone in the north west area.[19]
A step on from the PSBs was the IECC (Integrated Electronic Control Centre) system, a forerunner of the ROCs. The first IECC panel was installed at London Liverpool Street in 1989.[20]
After the railways in Britain were privatised in 1994,[16] [21] [22] staff from the then operating company, Railtrack, paid a visit to the Union Pacific Operating Center, USA in 1999. After viewing the facilities and seeing the control they decided that a small number of major operating centres was the way forward for UK operations. Just one centre was approved and built in 2003 at Saltley, near to Birmingham, as part of the West Coast Route Modernisation.[23] However this building was not connected for some time and whilst it was used by Network Rail staff, no signalling equipment was installed until 2006.[24]
See main article: ERTMS.
See main article: European Train Control System.
With the advent of the 'Digital Railway' project,[25] signalling methods such as ERTMS have been adopted as a way forward by Network Rail. There are two components of ERTMS, ECTS (European Train Control System) and TMS (Traffic Management System).
Whereas lineside signals operated by a signaller would control train movements, ETCS will signal trains via a computer without lineside apparatus. In effect, the train creates its own 'buffer zone' through a digital signal transmitted from the cab.[26] An onboard computer on the train will inform the driver of the 'allowable speed and movement of the train.'[27] TMS allows delays to be minimised through a computer running algorithms and deciding how best to return traffic patterns to normal.
These systems mean the removal of traditional signalling infrastructure and the signal boxes that go with them.
York IECC (Integrated Electronic Control Centre) is an example of an early version of a ROC. York IECC was opened in 1989[28] and controlled a large region in Yorkshire bounded by Gargrave, South Emsall, Selby, Northallerton, Cottingley (Leeds), Bramley and the Harrogate loop.[29] [30] The ROC, which opened in York on 12 September 2014,[31] superseded the York IECC in January 2015[32] and will eventually control the East Coast Main Line and associated lines in Lincolnshire, Yorkshire and the Humber and the North East of England. This means a King's Cross to Edinburgh train will be signalled by York ROC all the way from King's Cross to the Scottish Borders.[33]
Saltley ROC will become a remote signalling centre of Rugby. The facility at Saltley was opened as a bomb-proof[34] signalling centre for the West Coast Route Modernisation.[35] However, the inability to achieve a workable Traffic Management System (TMS)[36] without lineside signalling, meant an increased budget of £1.4 billion[37] and the building became a white elephant.[38] The structure was slowly integrated into a ROC function with signalling upgrades transferring responsibility to Saltley starting in 2006.[39] Because the interlocking mechanisms are in place, they will be left at Saltley and operated remotely from the Rugby ROC. What Saltley cannot do, that Rugby can, is host the human space needed for the signallers and train operating company (TOC) staff to work together.[24]
1 | Ashford | 1993 | Kent | Responsibility for control of Ashford IECC will be divided between Three Bridges and Gillingham.[40] | ||
2 | Basingstoke | April 2016[41] [42] | Wessex | Basingstoke Station (BE), Dorset Coast (PW) and the West of England Line (SE) are signalled from Basingstoke ASC. | ||
3 | Cardiff | 24 October 2010[43] | Wales | Known as WROC; Wales Rail Operating Centre. | ||
4 | Cowlairs | December 2008[44] | Scotland (West) | Was originally opened as the West of Scotland Signalling Centre (WSSC).[45] | ||
5 | Derby | 3 April 2008[46] | East Midlands | Was formerly known as the EMCC (East Midlands Control Centre)[47] | ||
6 | Didcot | March 2010[48] | Western | Also known as the Thames Valley Signalling Centre (TVSC).[49] | ||
1976[50] | Scotland (East) | Originally opened as a PSB, then transferred to IECC in 2006.[51] In updated notices released in November 2016, it was stated that there will now be only one ROC in Scotland at Cowlairs in Glasgow. All functions will be transferred there when necessary. | ||||
Gillingham | 1994.[52] | Kent | Opened in 1994 as the East Kent Signalling Centre.[53] | |||
9 | Manchester | 21 July 2014[54] | LNW (North) | Will control all lines in the north west in addition to West Coast Main Line from Crewe to Carlisle. | ||
10 | Romford | November 2016[55] [56] [57] [58] | East Anglia | Most other anglia signalling functions are controlled from the Service Delivery Centre at Liverpool St and from PSBs at Colchester and Cambridge. | ||
11 | Rugby | 13 November 2015[59] | LNW (South) | |||
12 | Saltley | 13 March 2003[60] | LNW (South) | First ROC Opened in 2003.[61] Functions will be transferred to Rugby ROC by 2019.[62] | ||
13 | Three Bridges | 7 January 2014[63] | Sussex | |||
14 | York | 12 September 2014[64] | LNE | Projected last signal box transfer on the network will be to York in 2056 when Morpeth box closes. |
Whilst the drive for the ROCs has been one of signalling upgrades, there are other benefits and detractions to the scheme. Around four thousand staff will lose their jobs over the course of the implementation programme leaving two thousand signallers in the ROCs.[66] The benefits of centralised control will be that the train operating company (TOC) staff will work alongside the Network Rail staff to allow cohesive problem solving such as resolving late running and last-minute platform changes. Network Rail have said that "The ROC is a key part of our strategy to improve reliability whilst driving down the cost of running and maintaining the railway."[67]
In 2016, it came to light that Network Rail had been hacked four times up to July 2016. As most of the rail network in the United Kingdom is analogue, it would not affect anything, but Network Rail have an aspiration for the digital rail Traffic Management System to go live in 2018. An online security company, who were not commissioned by, or working for Network Rail, discovered the hacks and declared that whilst the hacks were "probing and not disruptive," they could well be full of malicious software in the future.[68]
Network Rail responded by saying that
In 2017, Ian Prosser, the chief inspector of railways informed the Transport Select Committee that not enough had been done to alleviate the possibility of the ROCs becoming a single point of failure. Prosser highlighted higher workload on signallers and the contingencies needed in the event of a natural disaster disabling one of the ROCs.[69]
ROCs are mostly referred to as rail operating centres.[70] Even in Network Rail's own documentation they are sometimes referred to as railway operating centres.[71] Some of the railway press have referred to them as route operating centres[72] [73] and even regional operating centre.[74] [75]
This issue is further clouded by Network Rail having another ROC, the Railway Operational Code[76] and the signalling industry in the United Kingdom having a Remote Override Control.[77]