The Eiffel Tower, an immense stucture of exposed latticework supports made of puddle iron, was erected for the Paris Exposition of 1889. The Prince of Wales (later King Edward VII of England) officiated at the ceremonial opening. Of the 700 proposals submitted in a design competition, one was unanimously chosen, a radical creation from the French structural engineer Alexandre Gustave Eiffel (b. Dec. 15, 1832, d. Dec. 28, 1923), who was assisted in the design by engineers Maurice Koechlin and Emile Nouguier, and architect Stephen Sauvestre.

However, the controversial tower elicited some strong reactions, and a petition of 300 names — including those of Guy de Maupassant, Émile Zola, Charles Garnier (architect of the Opéra Garnier), and Alexandre Dumas fils — was presented to the city government, protesting its construction. The petition read, “We, the writers, painters, sculptors, architects and lovers of the beauty of Paris, do protest with all our vigour and all our indignation, in the name of French taste and endangered French art and history, against the useless and monstrous Eiffel Tower.”

Nature lovers thought that it would interfere with the flight of birds over Paris. But the Eiffel Tower was admired by Rousseau, Utrillo, Chagall, and Delaunay. It was almost torn down in 1909 at the expiration of its 20-year lease, but was saved because of its antenna — used for telegraphy at that time. Beginning in 1910 it became part of the International Time Service. French radio (since 1918), and French television (since 1957) have also made use of its stature. In the 1960s, it was the subject of a wonderful study by semiologist Roland Barthes.

Built to celebrate the science and engineering achievements of its age, soaring 300m / 984 ft. (320.75m / 1,052 ft. including antenna) and weighing 7000 tons, the structure consists of two visibly distinct parts: a base composed of a platform resting on four separate supports (called pylons or bents) and, above this, a slender tower created as the bents taper upward, rising above a second platform to merge in a unified column.

This unprecedented work, the tallest structure in the world until the Empire State Building was built about 40 years later, had several antecedents. Among them were the iron-supported railway viaducts designed by Eiffel, an arch bridge over the Douro River in Portugal with a span of 160 m (525 ft), and a design for a circular, iron-frame tower proposed by the American engineers Clarke and Reeves for the Centennial Exposition of 1876. Eiffel knew and publicly acknowledged this influence; he was no stranger to the United States, having designed the wrought-iron pylon inside Frederic Bartholdi’s Statue of Liberty in 1885. Later in the same year, he had also begun work on the cupola of the Nice observatory.

Eiffel was the leading European authority on the aerodynamics of high frames (he wrote “The Resistance of the Air” in 1913). In the construction of the Eiffel Tower, the curve of the base pylons was precisely calculated so that the bending and shearing forces of the wind were progressively transformed into forces of compression, which the bents could withstand more effectively. Such was Eiffel’s engineering wizardry that even in the strongest winds his tower never sways more than 4-1/2 inches. The superskyscrapers erected since 1960, such as the World Trade Center, were constructed in much the same way.

However difficult its birth may have been, the Tour Eiffel is now completely accepted by French citizens, and is internationally recognized as one of the symbols of Paris itself.

Facilities and Views
In the basements of the eastern and western pillars, one can visit the gargantuan 1899 machinery which powers the elevators, an astonishing spectacle reminiscent of a Jules Verne novel. From the Tower’s three platforms — especially the topmost — the view of Paris is superb. It is generally agreed that one hour before sunset, the panorama is at its best; don’t forget to bring your camera, and experiment with the f-stop settings to capture a dazzling sunset on the Seine. If you can’t be there in person, then check out a Live Aerial View of Paris with TF1′s webcam online: from the top of the Eiffel Tower, you can see Paris in real time, 24 hours a day, whatever the weather conditions in the French capital. To get the most out of this view of Paris, we suggest you surf their web site between 7:00 AM and 9:00 PM GMT (1:00 AM and 3:00 PM Eastern Time in the U.S.), when the City of Light is at its best.

First level: 57.63 meters (189 feet). Observatory from which to study the movements of the Eiffel Tower’s summit. Kiosk presentation about the mythic painting of the Eiffel Tower. Space CINEIFFEL: offers an exceptional panorama of sights from the Tower. Souvenir shops (yes, every tourist MUST have a miniature replica). Restaurant “Altitude 95″ (phone 01-45-55-20-04). Post office, with special stamps “Paris Eiffel Tower “. Panoramic gallery displaying the Monuments of Paris.

Second level: 115.73 meters (379 feet, 8 inches). Panorama of Paris. Telescopes, shops. Animated displays on the operation of the elevators. Jules Verne Restaurant (extremely expensive, reservations absolutely necessary; phone 01-45-55-61-44).

Third level: 276.13 meters (905 feet, 11 inches). Exceptional panoramic views, day or night, of Paris and its surroundings. Recently restored office, featuring wax reproductions of Gustave Eiffel and Thomas Edison in conversation (see photo. Panoramic guide displays to aid orientation. Dioramas presenting the history of this platform.

Probably the best approach to the tower is to take the Métro to the Trocadéro station and walk from the Palais de Chaillot to the Seine. Besides fabulous views, especially when the Trocadéro fountains are in full force, you get a free show from the dancers and acrobats who perform around the Palais de Chaillot. The vast green esplanade beneath the tower is the Parc du Champs-de-Mars, which extends all the way to the 18th-century École Militaire (Military Academy), at its southeast end. This formal lawn was once a parade ground for French troops.

The Eiffel Tower at night is one of the great sights of Paris and shouldn’t be missed. The gold lighting highlights the delicacy of the steelwork in a way that is missed in daylight. Skip the tour buses and pickpockets on Trocadéro and head up to the École Militaire for a more tranquil view.

Passenger lifts
Ground to second level , The original lifts to the first and second floors were provided by two companies. Both companies had to overcome many technical obstacles as neither company (or indeed any company) had experience with installing lifts climbing to such heights with large loads. The slanting tracks with changing angles further complicated the problems. The East and West lifts were supplied by the French company Roux Combaluzier Lepape, using hydraulically powered chains and rollers. Contemporary engravings of the lift cars show that the passengers were seated at this time but it is not clear whether this was conceptual. It would be unnecessary to seat passengers for a journey time of around a couple of minutes. The North and South lifts were provided by the American Otis company using car designs similar to the original installation but using an improved hydraulic and cable scheme. The French lifts had a very poor performance and were replaced with the current installations in 1897 (West Pillar) and 1899 (East Pillar) by Fives-Lille using an improved hydraulic and rope scheme. Both of the original installations operated broadly on the principle of the Fives-Lille lifts.

The Fives-Lille lifts from ground level to the first and second levels are operated by cables and pulleys driven by massive water-powered pistons. The hydraulic scheme was somewhat unusual for the time in that it included three large counterweights of 200 tonnes each sitting on top of hydraulic rams which doubled up as accumulators for the water. As the lifts ascend the inclined arc of the pillars, the angle of ascent changes. The two lift cabs are kept more or less level and indeed are level at the landings. The cab floors do take on a slight angle at times between landings.

The principle behind the lifts is similar to the operation of a block and tackle but in reverse. Two large hydraulic rams (over 1 metre diameter) with a 16 metre travel are mounted horizontally in the base of the pillar which pushes a carriage (the French word for it translates as chariot and this term will be used henceforth to distinguish it from the lift carriage) with 16 large triple sheaves mounted on it. There are 14 similar sheaves mounted staticly. Six wire ropes are rove back and forth between the sheaves such that each rope passes between the 2 sets of sheaves 7 times. The ropes then leave the final sheaves on the chariot and passes up through a series of guiding sheaves to above the second floor and then via a pair of triple sheaves back down to the lift carriage again passing guiding sheaves.

This arrangement means that the lift carriage complete with its cars and passengers travels 8 times the distance that the rams move the chariot which is the 128 metres from the ground to the second floor. The force exerted by the rams also has to be 8 times the total weight of the lift carriage, cars and passengers plus extra to cater for various losses such as friction. The hydraulic fluid was water, normally stored in the 3 accumulators complete with counterbalance weights. To make the lift ascend, water was pumped using an electrically driven pump from the accumulators to the two rams. Since the counterbalance weights provided much of the pressure required, the pump only had to provide the extra effort. For the descent, it was only necessary to allow the water to flow back to the accumulators using a control valve. The lifts were operated by an operator perched precariously underneath the lift cars. His position (with a dummy operator) can still be seen on the lifts today.

The Fives-Lille lifts were completely upgraded in 1986 to meet modern safety requirements and to make the lifts easier to operate. A new computer controlled system was installed which completely automated the operation. One of the three counterbalances was taken out of use, and the cars were replaced with a more modern and lighter structure. Most importantly, the main driving force was removed from the original water pump such that the water hydraulic system provided only a counterbalancing function. The main driving force was transferred to a 320 kW electrically driven oil hydraulic pump which drives a pair of hydraulic motors on the chariot itself thus providing the motive power. The new lift cars complete with their carriage and a full 92 passenger load weigh 22 tonnes.

Due to elasticity in the ropes and the time taken to get the cars level with the landings, each lift in normal service takes an average of 8 minutes and 50 seconds to do the round trip spending an average of 1 minute and 15 seconds at each floor. The average journey time between floors is just 1 minute.

The original Otis lifts in the North and South pillars in their turn proved inferior to the new (in 1899) French lifts and were scrapped from the south pillar in 1900 and from the north pillar in 1913 after failed attempts to re-power them with an electric motor. The north and south pillars were to remain without lifts until 1965 when increasing visitor numbers persuaded the operators to install a relatively standard and modern rope hoisted system in the north pillar using a rope hauled counterbalance weight, but hoisted by a block and tackle system to reduce its travel to one third of the lift travel. The counterbalance is clearly visible within the structure of the North pillar. This latter lift was upgraded in 1995 with new cars and computer controls.

The South tower acquired a completely new fairly standard electrically driven lift in 1983 to serve the Jules Verne restaurant. This was also supplied by Otis.

A further 4 tonne service lift was added to the south pillar in 1989 by Otis to relieve the main lifts when moving relatively small loads or even just maintenance personnel.

The east and west hydraulic (water) lift works are on display and, at least in theory, are open to the public in a small museum located in base of the East and West tower, which is somewhat hidden from public view. Because the massive mechanism requires frequent lubrication and attention, public access is often restricted. However, when open, the wait times are much less than the other, more popular, attractions. The rope mechanism of the North tower is visible to visitors as they exit from the lift.

Second to third level , The original lift from the second to the third floor were also of a water powered hydraulic design supplied by Léon Edoux. Instead of using a separate counterbalance, the two lift cars counterbalanced each other. A pair of 81 metre long hydraulic rams were mounted on the second level reaching nearly half way up to the third level. A lift car was mounted on top of the rams. Ropes ran from the top of this car up to a sheave on the third level and back down to a second car. The result of this arrangement was that each car only travelled half the distance between the second and third levels and passengers were required to change lifts halfway walking between the cars along a narrow gangway with a very impressive and relatively unobstructed downward view. The 10 tonne cars held 65 passengers each or up to 4 tonnes.

One interesting feature of the original installation was that the hoisting rope ran through guides to retain it on windy days to prevent it flapping and becoming damaged. The guides were mechanically moved out of the way of the ascending car by the movement of the car itself. In spite of some antifreeze being added to the water that operated this system, it nevertheless had to close to the public from November to March each year.

The original lifts complete with their hydraulic mechanism were completely scrapped in 1982 after 97 years of service. They were replaced with two pairs of relatively standard rope hoisted cars which were able to operate all the year round. The cars operate in pairs with one providing the counterbalance for the other. Neither car can move unless both sets of doors are closed and both operators have given a start command. The commands from the cars to the hoisting mechanism are by radio obviating the necessity of a control cable. The replacement installation also has the advantage that the ascent can be made without changing cars and has reduced the ascent time from 8 minutes (including change) to 1 minute and 40 seconds. This installation also has guides for the hoisting ropes but they are electrically operated. The guide once it has moved out of the way as the car ascends automatically reverses when the car has passed to prevent the mechanism becoming snagged on the car on the downward journey in the event it has failed to completely clear the car. Unfortunately these lifts do not have the capacity to move as many people as the 3 public lower lifts and long queues to ascend to the third level are common. Most of the intermediate level structure present on the tower today was installed when the lifts were replaced and allows maintenance workers to take the lift half way.

The replacement of these lifts allowed the restructuring of the criss-cross beams in upper part of the tower and further allowed the installation of two emergency staircases. These replaced the dangerous winding stairs that were installed when the tower was constructed.

Interesting Facts
During its lifetime, the Eiffel Tower has witnessed a few strange scenes, including being scaled by a mountaineer in 1954, and two Englishmen parachuting off it in 1984. In 1923, the journalist Pierre Labric (who was later to become mayor of Montmartre) rode a bicycle down from the first level; some accounts say he rode down the stairs, others suggest the exterior of one of the tower’s four legs which slope outward.

Politics have also played a role in its life. During World War II, the Germans hung a sign on it that read: “Deutschland Siegt Auf Allen Fronten” (“Germany is victorious on all fronts”). In 1958, a few months before Fidel Castro’s rise to power, Cuban revolutionaries hung their red-and-black flag from the first level, and, in 1979, an American from Greenpeace hung one that read: “Save the Seals”. In 1989, the Tower celebrated its centennial with music and fireworks (the show lasted 89 minutes).
Operation

The Eiffel Tower is owned by the City of Paris, which has subcontracted its maintenance and daily operations since 2005 to SETE (Société d’Exploitation de la Tour Eiffel), a public utility.

More than 500 people bring the Eiffel Tower to life each day. About one half are employed by SETE, the others are concessionaires (souvenir boutiques, restaurants, telescope operations, ATMs, behind-the-scene tours) and civil service employees (police, fire personnel, post office, weather).

Since the beginning of the 20th century, the tower has been used for radio transmission. Until the 1950s, an occasionally modified set of antenna wires ran from the summit to anchors on the Avenue de Suffren and Champ de Mars. They were connected to long-wave transmitters in small bunkers; in 1909, a permanent underground radio centre was built near the south pillar and still exists today. On 20 November 1913, the Paris Observatory, using the Eiffel Tower as an antenna, exchanged sustained wireless signals with the United States Naval Observatory which used an antenna in Arlington, Virginia. The object of the transmissions was to measure the difference in longitude between Paris and Washington, D.C. Today, both radio and televisioni stations broadcast their signals from the top of the Eiffel.