Tunnelling began on the British side on December 11, 1987. The tunnel took three years to build, cost £10 billion pounds to build, employed 15,000 workers and cost 10 lives. First contact between the two sides was made in October 1990. Despite removing enough earth to fill Wembley stadium 13 times over, the two tunnels were only a few centimetres out of alignment.

The tunnel is now fully functioning. It extends for 31 miles under the English channel (or the French La Manche depending on your perspective). The deepest point is 114.9m below sea level, compared to the average London Underground depth of 24.38m. There are two main train tunnels, plus a small maintenance access tunnel.

About The Tunnel
The Channel Tunnel is the longest undersea tunnel in the world. The section under the sea is 38km long. The three tunnels, each 50km long, were bored at an average 40m below the sea bed, and link Folkestone in Kent to Coquelles in Pas-de-Calais.

Eurotunnel shuttles, Eurostar and national freight trains run in the two single track and single direction tunnels. These are connected to a central service tunnel by cross-passages situated every 375m. The service tunnel allows access to maintenance and emergency rescue teams and serves as a safe haven if passengers need to be evacuated in an incident. The service tunnel is a road tunnel used by electric and diesel-powered vehicles. Air pressure is higher in the service tunnel to prevent the ingress of smoke in case of a fire in one of the rail tunnels.

The two rail tunnels are 7.6m in diameter and 30m apart. Each rail tunnel has a single track, overhead line equipment (catenary) and two walkways (one for maintenance purposes and the other for use in the event of an emergency evacuation and on the side nearest the service tunnel). The walkways are also designed to maintain a shuttle upright and in a straight line of travel in the unlikely event of a derailment.

The service tunnel is 4.8m in diameter and lies between the two rail tunnels 15m away from each of them. In normal operations shuttles use the south tunnel in the France – UK direction, and the north tunnel when travelling from the UK to France.

Two undersea crossovers bring flexibility of operation as trains can pass from one tunnel to the other during night maintenance periods to isolate a section of tunnel.

The track in each rail tunnel has two continuously welded rails laid on pre-cast concrete supports embedded in the concrete track bed.

Fixed equipment in the tunnels comes under four categories: electricity and catenary, rail track and signaling, mechanical systems and control and communications.

Cooling pipes, fire mains, signalling equipment and cables are fixed to the sides of the tunnels and are fed by cooling plants at Samphire Hoe in the UK and Sangatte in France.

The overhead catenary supplies traction power to the shuttles as well as to other trains using the Tunnel, e.g. Eurostar and international rail freight trains. The catenary is divided into sections, so that maintenance work can be carried out in stages. Electrical power supplying the tunnels, drainage pumps, lighting and the trains, is provided by substations on each side of the Channel. In the event of loss of power from one side, the entire system can be supplied from the other side.

The fixed lighting installations can be switched on from the control centre or manually from within the tunnels. Various fire-protection and detection systems are installed at points along the length of the tunnels.

Control Center

The entire Eurotunnel transport system is controlled from the RCC (Rail Control Centre). There are two centres, one on each terminal, and each can take turns to take over control of the system. The RCC manages all rail traffic (trains and shuttles) in the tunnels and on the terminals.

The system is in two parts, the Rail Traffic Management (RTM), which controls the rail traffic system, and the Engineering Management System (EMS) which controls the fixed equipment such as ventilation, lighting, power for the catenary, etc.

Although the transport system is automated, controllers are in attendance 24 hours a day, ready to take manual control in the event of technical failure.

Signalling

The signalling system in the Channel Tunnel is known as TVM 430: it functions by means of data transmission from track to train and is almost identical to the system used on the high-speed TGV Nord-Europe. Instructions and data are transmitted along the track and then to the locomotive driver by indicator lights in the cab.
All Eurotunnel trains are fitted with vigilance devices and full automatic train protection which minimises the risk of collision in the event of a human error.

After travelling through the tunnel, the through-trains operated by the railway companies then continue their journey on the UK or French rail networks, which are connected to the tunnel tracks at Dollands Moor and Frethun, respectively.

The shuttles operated by Eurotunnel remain within the Eurotunnel system: they travel on a rail loop between the Folkestone and Coquelles terminals, using the south tunnel when going from France to the UK and the north tunnel when going from the UK to France.

Service Tunnel Vechiles

A vehicle was specifically designed for travel in the service tunnel. It is multi-functional and is used for maintenance operations and in case of incidents, with the aim of reaching the scene of an incident in minimum time.

Locomotives

All locomotives are of the Bo-Bo-Bo configuration, i.e. they are equipped with three bogies, each with two motorised axles. This provides the dual advantage of excellent adhesion between wheel and rail and improved performance.

Each Eurotunnel shuttle in commercial operation has two locomotives, one at each end of the shuttle and is about 800m long.

Eurotunnel uses two types of locomotives built by ABB Brush: the original 5.6MW (Mega Watt) locomotives and the new generation 7MW locomotives, the most powerful in the world. Part of the initial 5.6MW locomotive fleet will gradually be upgraded to 7MW in March 2007, making it possible for freight shuttles to have a capacity of 12.6MW - crossing times will be guaranteed even with a heavier load of lorries.

The Passenger Shuttles

Each of the nine Eurotunnel passenger shuttles consists of two separate halves, or rakes. One has a single deck for coaches, minibuses, caravans and vehicles higher than 1.85m. The other transports cars and motorcycles on a double deck.

The fleet of nine passenger shuttles therefore comprises 108 single deck carriages, 108 double deck carriages, 36 double and single deck loading wagons. A complete passenger shuttle can carry 12 coaches and 120 cars.

The passenger shuttles were built in stainless steel by the Canadian group Bombardier Inc., BN (Belgium) and ANF (France). A passenger shuttle is made up of 24 carriages and four loading/unloading wagons in the following configuration:

Carriages have been insulated with materials used in the aeronautic industry, providing the best protection against high thermal variations and able to resist fire for 30 minutes. Each carriage is closed at each end with specially designed fire resistant doors, and equiped with smoke, vapour, heat and fire detectors.