Funicular: Difference between revisions

A funicular (/fjuːˈnɪkjʊlər/, /f(j)ʊ-/, /fə-/)^[1] is a type of cable railway system which connects points along a railway track laid on a steep slope. The system is characterized by two counterbalanced carriages (also called cars or trains) permanently attached to opposite ends of a haulage cable, which is looped over a pulley at the upper end of the track.^[2][3] The result of such a configuration is that the two carriages move synchronously: as one ascends, the other descends at an equal speed. This feature distinguishes funiculars from inclined elevators, which have a single car that is hauled uphill.^[2][3][4]

The term funicular derives from the Latin word funiculus, the diminutive of funis, meaning 'rope'.^[5]

In a funicular, neither of the two carriages is equipped with an engine or uses any power to move along the track. Instead, both cars are permanently connected to the opposite ends of the same cable, known as a haul rope; this haul rope runs through a system of pulleys, whose movement is controlled in the engine room (usually at the upper end of the track). If the railway track is not perfectly straight, the cable is guided along the track using sheaves – unpowered pulleys that simply allow the cable to change direction. While one car is pulled upwards by one end of the haul rope, the other car descends the slope at the other end. Since the weight of the two cars is counterbalanced (except for the weight of passengers), no lifting force is required to move them – the engine only has to lift the cable itself and the excess passengers, and supply the energy lost to friction by the cars' wheels and the pulleys.^[2][6]

For passenger comfort, funicular carriages are usually (although not always) constructed so that the floor of the passenger deck is horizontal, and not necessarily level with the sloped track.

In some installations, the cars are also attached to a second cable – bottom towrope – which runs through a pulley at the bottom of the incline. In these designs, one of the pulleys must be designed as a tensioning wheel to avoid slack in the ropes. One advantage of such an installation is the fact that the weight of the rope is balanced between the carriages; therefore, the engine no longer needs to use any power to lift the cable itself. This practice is used on funiculars with slopes below 6%, funiculars using sledges instead of carriages, or any other case where it is not ensured that the descending car is always able to pull out the cable from the pulley in the station on the top of the incline.^[7] It is also used in systems where the engine room is located at the lower end of the track (such as the upper half of the Great Orme Tramway) – in such systems, the cable that runs through the top of the incline is still necessary to prevent the carriages from coasting down the incline.^[8]

In most modern funiculars, the propulsion is provided by an electric motor which is linked via a speed-reducing gearbox to a large pulley – a drive bullwheel. The bullwheel in its turn transfers its torque to the haul rope by friction. The bullwheel has two grooves: after the first half turn around it the cable returns via an auxiliary pulley. This arrangement has the advantage of having twice the contact area between the cable and the groove, and returning the downward-moving cable in the same plane as the upward-moving one. Modern installations also use high friction liners to enhance the friction between the bullwheel grooves and the cable.^[6][9][10]

For emergency and service purposes two sets of brakes are used at the engine room: the emergency brake grips directly the bullwheel, the service brake is mounted at the high speed shaft of the gear. In case of an emergency the cars are also equipped with spring-applied, hydraulically opened rail brakes.^[10]

First funicular's caliper brakes which clamp each side of the crown of the rail were invented by the Swiss entrepreneurs Franz Josef Bucher and Josef Durrer and implemented at the Stanserhorn funicular [de], opened in 1893.^[11][12] The Abt rack and pinion system was also used at some funiculars for speed control or emergency braking.^[2][6]

A few funiculars have been built using water tanks under the floor of each car that are filled or emptied until just sufficient imbalance is achieved to allow movement. The car at the top of the hill is loaded with water until it is heavier than the car at the bottom, causing it to descend the hill and pull up the other car. The water is drained at the bottom, and the process repeats with the cars exchanging roles. The movement is controlled by a brakeman using the brake handle of the rack and pinion system engaged with the rack mounted between the rails.^[2][6]

The Bom Jesus funicular built in 1882 near Braga, Portugal is one of the extant systems of this type. Another example, the funicular Neuveville - St-Pierre [fr] in Fribourg, Switzerland,^[13] is of particular interest as it utilizes waste water, coming from a sewage plant at the upper part of the city.^[14]

Some funiculars of this type were later converted to electrical power. For example, the Giessbachbahn in the Swiss canton of Berne, opened in 1879, was originally powered by water ballast. In 1912 its energy provision was replaced by a hydraulic engine powered by a Pelton turbine. In 1948 this in turn was replaced by an electric motor.^[2]

East Hill Cliff Railway in Hastings, UK – a four-rail funicular

Angels Flight in Los Angeles, USA – a three-rail funicular

Nazaré Funicular in Nazaré, Portugal – a two-rail funicular

There are three main rail layouts used on funiculars; depending on the system, the track bed can consist of four, three, or two rails.

• Early funiculars were built to the four-rail layout, with two separate parallel tracks and separate station platforms at both ends for each vehicle. The two tracks are laid with sufficient space between them for the two carriages to pass at the midpoint. While this layout requires the most land area, it is also the only layout that allows both tracks to be perfectly straight, requiring no sheaves on the tracks to keep the cable in place. Examples of four-rail funiculars are the Duquesne Incline in Pittsburgh, Pennsylvania, and most cliff railways in the United Kingdom.

• In three-rail layouts, the middle rail is shared by both carriages, while each car runs on a different outer rail. To allow the two cars to pass at the halfway point, the middle rail must briefly split into two, forming a passing loop. Such systems are narrower and require less rail to construct than four-rail systems; however, they still require separate station platforms for each vehicle.^[2]

• In a two-rail layout, both cars share the entire track except at the passing loop in the middle. This layout is the narrowest of all and needs only a single platform at each station (though sometimes two platforms are built: one for boarding, one for alighting). However, the required passing loop is more complex and costly to build, since special turnout systems must be in place to ensure that each car always enters the correct track at the loop. Furthermore, if a rack for braking is used, that rack can be mounted higher in three-rail and four-rail layout, making it less sensitive to choking in snowy conditions.^[7]

Some funicular systems use a mix of different track layouts. An example of this arrangement is the lower half of the Great Orme Tramway, where the section “above” the passing loop has a three-rail layout (with each pair of adjacent rails having its own conduit which the cable runs through), while the section “below” the passing loop has a two-rail layout (with a single conduit shared by both cars).

Some four-rail funiculars have their tracks interlaced above and below the passing loop; this allows the system to be nearly as narrow as a two-rail system, with a single platform at each station, while also eliminating the need for the costly junctions either side of the passing loop. The Hill Train at the Legoland Windsor Resort is an example of this configuration.

Abt switch

In the case of two-rail funiculars, various solutions exist for ensuring that a carriage always enters the same track at the passing loop.

One such solution involves installing switches at each end of the passing loop. These switches are moved into their desired position by the carriage's wheels during trailing movements (i.e. away from the passing loop); this procedure also sets the route for the next trip in the opposite direction. The Great Orme Tramway is an example of a funicular that utilizes this system.

Another turnout system, known as the Abt switch, involves no moving parts on the track at all. Instead, the carriages are built with an unconventional wheelset design: the outboard wheels have flanges on both sides, whereas the inboard wheels are unflanged (and usually wider to allow them to roll over the turnouts more easily). The double-flanged wheels keep the carriages bound to one specific rail at all times. One car has the flanged wheels on the left-hand side, so it follows the leftmost rail, forcing it to run via the left branch of the passing loop; similarly, the other car has them on the right-hand side, meaning it follows the rightmost rail and runs on the right branch of the loop. This system was invented by Carl Roman Abt and first implemented on the Lugano Città–Stazione funicular in Switzerland in 1886;^[2] since then, the Abt turnout has gained popularity, becoming a standard for modern funiculars.^[9] The lack of moving parts on the track makes this system cost-effective and reliable compared to other systems.

The majority of funiculars have two stations, one at each end of the track. However, some systems have been built with additional intermediate stations. Because of the nature of a funicular system, intermediate stations are usually built symmetrically about the mid-point; this allows both cars to call simultaneously at a station. Examples of funiculars with more than two stations include the Wellington Cable Car in New Zealand (five stations, including one at the passing loop)^[15] and the Carmelit in Haifa, Israel (six stations, three on each side of the passing loop).^[16]

A few funiculars with asymmetrically-placed stations also exist. For example, the Petřín funicular in Prague has three stations: one at each end, and a third (Nebozízek) a short way up from the passing loop.^[17] Because of this arrangement, carriages are forced to make a technical stop a short distance down from the passing loop as well, for the sole purpose of allowing the other car to call at Nebozízek.

A number of cable railway systems which pull their cars on inclined slopes were built since the 1820s. In the second half of the 19th century the design of a funicular as a transit system emerged. It was especially attractive in comparison with the other systems of the time as counterbalancing of the cars was deemed to be a cost-cutting solution.^[2]

The first line of the Funiculars of Lyon (Funiculaires de Lyon) opened in 1862, followed by other lines in 1878, 1891 and 1900. The Budapest Castle Hill Funicular was built in 1868–69, with the first test run on 23 October 1869. The oldest funicular railway operating in Britain dates from 1875 and is in Scarborough, North Yorkshire.^[18] In Istanbul, Turkey, the Tünel has been in continuous operation since 1875 and is both the first underground funicular and the second-oldest underground railway. It remained powered by a steam engine up until it was taken for renovation in 1968.^[19]

Until the end of the 1870s, the four-rail parallel-track funicular was the normal configuration. Carl Roman Abt developed the Abt Switch allowing the two-rail layout, which was used for the first time in 1879 when the Giessbach Funicular opened in Switzerland.^[7]

In the United States, the first funicular to use a two-rail layout was the Telegraph Hill Railroad in San Francisco, which was in operation from 1884 until 1886.^[20] The Mount Lowe Railway in Altadena, California, was the first mountain railway in the United States to use the three-rail layout. Three- and two-rail layouts considerably reduced the space required for building a funicular, reducing grading costs on mountain slopes and property costs for urban funiculars. These layouts enabled a funicular boom in the latter half of the 19th century.

In 1880 the funicular of Mount Vesuvius inspired the Italian popular song Funiculì, Funiculà. This funicular was destroyed repeatedly by volcanic eruptions and abandoned after the eruption of 1944.^[21]

According to the Guinness World Records, the smallest public funicular in the world is the Fisherman's Walk Cliff Railway in Bournemouth, England, which is 39 metres (128 ft) long.^[22][23]

Stoosbahn in Switzerland, with a maximum slope of 110% (47.7°), is the steepest funicular in the world.^[24]

The Lynton and Lynmouth Cliff Railway, built in 1888, is the steepest and longest water-powered funicular in the world. It climbs 152 metres (499 ft) vertically on a 58% gradient.^[25]

The city of Valparaiso in Chile used to have up to 30 funicular elevators (Template:Lang-es). The oldest of them is dating from 1883. 15 remain with almost half in operation, and others in various stages of restoration.

The Carmelit in Haifa, Israel, with six stations and a tunnel 1.8 km (1.1 mi) long, is claimed by the Guinness World Records as the "least extensive metro" in the world.^[16] Technically, it is an underground funicular.

The Dresden Suspension Railway (Dresden Schwebebahn), which hangs from an elevated rail, is the only suspended funicular in the world.^[26]

Odessa Funicular in Odessa, Ukraine

Kakola Funicular in Turku, Finland

Despite their names, neither system is a true funicular.

Some systems around the world are branded as funiculars, even though in reality they are inclined elevators. Unlike a funicular, inclined elevators operate independently on the slope rather than in interconnected pairs, and lift is required to haul the cars uphill.^[3]

A notable example of this phenomenon is Paris' Montmartre Funicular. Its formal title is a relic of its original configuration, when its two cars operated as a counterbalanced, interconnected pair, always moving in opposite directions, thus meeting the definition of a funicular. Hoowever, the system has since been redesigned, and now uses two independently-operating cars that can each ascend or descend on demand, qualifying as a double inclined elevator; the term "funicular" in its title is retained as a historical reference.^[27][28][4]

• Cable car (railway)
• Gravity railroad
• Inclined elevator
• List of funicular railways
• Steep grade railway

Look up funicular in Wiktionary, the free dictionary.

• Funimag, the first web magazine about funiculars