L'électricité - Histoire d'une révolution

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Hello my dear friends!

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A museum that showcases an intagible object, often invisible?

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It's possible! And it exists, here, in Mulhouse. We are in the

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Electropolis Museum, whose principal sponsor is the EDF group. Devoted to electricity,

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its history, from the first observations in Antiquity up to its industrial operation,

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including the spectacular experimentations with "the electrical fairy"

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who enchanted the masses between the ends of the 18th and 19th centuries.

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Electricty! What would our 21st century human lives be like without it?

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It wouldn't be total darkness.: we would still light with candles

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or oil. On the other hand, no video games.Actually no video period.

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And no video makers!!! No television, radio, not even movies

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process described by the chinese ideograms as: "electric shadow"

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Electricity used nowdays as much for transmitting the lights of culture and knowledge

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as the simple physics light, it wouldn't be as much obscurity that would threaten the world

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as obscurantism. Electricity links us together as never before

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in human history. By telegram, then telephone, today

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with internet, it allows us to link our voices, images, and with the expansion

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of electrical transportation, it will also soon be the one taking us to the end of the street

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as the end of the world. For a little over a century, electricity

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illuminate the world and transformed our lives as no other invention since

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fire or agriculture, millenia ago. But is it strictly speaking an invention?

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In reality, not at all. Neither fire nor electricity are inventions.

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To be exact, it isn't even a discovery! Not only is electricity

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in the heart of the matter since the Universes Genesis, the electromagnetic forces

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being part of the keystones that make matter possible, but for

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human beings, this electricity, invisible to the naked eye, has nevertheless

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manifested through various phenomenon leaving our ancestors sometimes in awe,

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mostly terrified, since the first manifestation of this electrical force

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we think of is, of course, the thunderbolt, whose power and destruction

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potential inspired many myths to mankind. But other manifestations

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have awakened the inquisitivness of the first civilisations. Magnetism, whose theoretical convergence

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with electricity will only happen centuries later, is one of those

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phenomenon. For example, in 600 BC, the greek scholar Thales of Miletus

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noticed that when you rub yellow amber against certain materials

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this substance would attract small feathers or straw.

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And, independantly of its'electrostatic properties, Greeks called yellow amber "elektron"

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a word promised to a bright future! The Ancients had also identified

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other natural magnetization, like wools' triboelectric charging or

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lodestones. But they considered these phenomenons and other natural

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oddities as the manifestation of the soul of things, at best a

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characteristic of life. And how to blame them when one of the main

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sources of electricity in nature, other than thunder, are electrical fish, like torpedos

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or cat-fish. And this natural electricity, able to dispense electricals shocks

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from 60 to 350 volts, was used since Antiquity, especially in the medical field,

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to treat migraines or gout attacks with what one can consider as

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distant ancestor to electroshocks!

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But it's in the 17th century, with the birth of experimental science, that electricity

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really starts its epic saga. Queen Elizabeth the firsts' doctor named

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William Gilbert , after comparing Earth to a huge magnet in 1600,

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explained the poles magnetism, classified the matter that he first defines

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as "electric". Magnetism and electricity. Following Isaac Newton's

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works, Gravity is associated and are studied together.

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In 1660, Otto von Guericke managed to create sparks by rubbing a rotating brimstone

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It's a first one in the production of experimental electricity!

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From Brimstone, Christiaan Huygens goes to Amber, then Francis Hawkbee replaces

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Amber by glass, producing more and more impressive sparks.

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Beyond these haphazard experimentations, theory also

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gets a boost. Stephen Gray demonstrates that the "electrical vertue"

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as it was called back then, can be carried along silk threads, then metal.

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Casually, from static, electricity slowly becomes current! The French

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Charles-Francis de Cisternai du Fay highlights 2 kinds of electricity:

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"vitreous" and "resinous", that later Benjamin Franklin will redefine as

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"positive" and "negative".

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We are primed for the conception of generators, accumulators and other batteries

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essential to give electricity

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a real use beyond scientific curiosity. Two men,

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a prussian: Ewald Georg von Kleist and a Dutch: Peter van Musschenbroek, are in a matter of months,

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each on their own, between october 1745 and april 1746, change bottles

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into the ancestor of the electrical condenser .

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These milk bottles

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once in a battery set-up, pun intended, allow to accumulate

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electricity up to a unprecedented charge. From there,

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these gentlemen scholars must be careful where they put their fingers

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because the shocks increase in strength! It starts to sting pretty hard!

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Some actually have fun making a group of people jump like the prankster abbot Jean-Antoine de

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Nollet, who kindly electrifies 240 soldiers to the great pleasure of

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Louis the 15th and his Court. He'll do even better later by sending a divine

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shock to a chain of Carthusian monks linked together by a 3 km (1.86mil) long

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metal thread. Undoubtedly sparks are flying between men of science

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and the public. During the 19th century, electricity puts on a show more often in public.

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You have showmen who organise exhibitions but also scientists

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who, in between serious experiments, show to an amazed public the effect

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of an electrical charge on hair, or launch explosions and

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ignite flammable mixtures from their fingertips, once isolated from the floor

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and sufficiently charged up. The show is guaranteed! More seriously, the Italian

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Alessandro Volta, on Brumaire the 16th year 10, or, if you prefer, the 7th of November 1801, shows

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Napoleon Bonaparte, future Emperor, his electrical battery. This stack

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of copper and zinc bathing in acide marked an important moment

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in the History and the "electrical fairy": its the advent of DC current and the

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starting point of multiple applications. Volta proves once and for all, against

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his rival Galvani, that electricity is a physical phenomenon and not a biological one.

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Research, "galvanised" par future perspectives, progresses by leaps and bounds under

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the impulse of these 2 men that will give their names to electrical measuring units

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and define the notions of current, charge and voltage: the Charles-Augustin Coulomb,

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Andre-Marie Amper, and Georg Ohms. There are the theoricians, but also,

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always seeking the next innovation, genious tinkerers like the German

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Heinrich Ruhmkorff who created the first induction coil. Or all those who

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helped create a machine capable of converting electricity into movement,

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in other words, the design of a real electrical motor.

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In this field, if you have to mention the English Michael Faraday, France

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as well, with Jean-Gustave Bourbouze's motor.

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It's the same design and principles as in the steam-engine

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with pistons, balancers and rods. Except here, the whole system is propelled by a simple

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electrical source activating electro-magnets, and not the burning of charcoal

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needed for steam. A clean engine. Note that at the

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end of the 19th century, the burgeoning motor car hesitated between electric and fossil fuel

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On board his prototype called "Never Satisfied", the Belgian

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Camille Jenatzi went over 100km/h (60mph) thanks to his two electrical engines

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with a total power of 50 kilowatts, equivalent to 68 horse power. The car

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could have been electric from the start but, unfortunately for the environment

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it's the combustion engine who'll win for the following 100 years.

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Too bad. But us, in the beginning of the 21st century, we know

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we haven't heard the last of the electrical car!

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If electrical energy start, with different engines, to convert into mouvement

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the opposite is also true: in 1869 the Franco-belgian Zenobe Gramme devises his Dynamo

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considered as the first real industrial power generator.

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And it's here, in Mulhouse, that Gramme will demonstrate

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his Dynamo to the manufacturers. It's also here that is was produced and sold

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by Ducommun manufacturer. Amongst the first clients, the thread-making

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DMC company, making it the first factory to use electrical lighting

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in 1878. But one of the most game changing applications

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of this new electrical knowledge is without a doubt the telegraph.

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let's rewind a little: if we already could have electric impulses run along a thread,

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it's in the early 1830's, thanks to the american

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Samuel Morse and his international code that, for the first time,

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information traveled at the speed of light. As soon as 1851, the telegraph

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linked France to England via an underwater cable. 15 years later,

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it was Europ to the States. This means of instantaneous communication

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is a true game changer and the first step in a process that

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makes our planet smaller and more connected. In a way it's telepathy

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that becomes a reality. With Alexander Graham Bell's telephone,

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this kind of "telepathy" makes another leap forward!

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After allowing, with the telegraph, the circulation of thoughts, the cabling systems

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quickly allowed the circulation of lights. With the arrival

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of electrical lighting in the streets, theaters, retail stores and finally

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the homes, the powerful electrical fairy illuminated the world little by little. In the US

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Thomas Alva Edison, "the wizard of Menlo Park", by establishing General Electric

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was the first to create a complete electrical distribution system, with

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production center, distribution network and of course at the end of it

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the possibility to connect the famous Bulb he perfected. Progressing with difficulty

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because of lobby pressures from the gas companies (yep! already!) expansion

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of electrical light was unstopable.

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At night, our planet Earth shines with the brightness of a thousand flames, as if

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the planet was reflecting the stars around it.

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And here we are at the beginning of the 20th century, the one of transformations.

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The world expos center all their attention on electricity and its applications.

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Soon, the production of electricity was involving the power of rivers

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with hydroelctric plants, always more daunting, the power of wind

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and tides, but also the power of the atom. But for the moment in this year 1901,

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one of the most impressive devices to create electricity is: "The BIG machine"

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It's the main attraction

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of the electropolis museum, the Sulzer- BBC power generator. A honey-smooth device

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straight out of a steampunk dream! A monster made of copper, cast iron and steel that Jules Verne

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wouldn't deny. Actually, it is the type of technology that this

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great advocate for electricity is said to have set in the heart of the Nautilus, as unique

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and powerful energy source. The big Sulzer-BBC is a link

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between the first and second industrialisation, between the 19th and 20th century,

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between steam and electricity. Indeed, the Brown-Boveri alternator and its massive 6 meters (19.6ft)

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of diameter, capable of delivering 900 kilowatts for an output of 400 volts,

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was originally powered by a steam engine. When I say we're in Steampunkland!

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The furnaces for the Sulzer produced

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12 bars (174 Psi) of pressure in its cylinders which, through a system of pistons, rods and cranks

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moved the huge alternator wheel. After 50 years of good services

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in the DMC factory in Mulhouse, this jewel of industrial heritage barely

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escaped scrapping. Entirely restaured in the 1980's, the big machine still

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works today to the visitor's delight as part of a multimedia show

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here, in the museum that was built for and around it.

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Now, no more furnaces, but electrical motors, probalby

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greener, but the big machine continues to amaze the spectators,

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even if it's imposing rotor only goes at 21 rev per minute, representing only

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a fourth of its original speed.

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Another impressive piece in this collection is this Pelton hydroelctrical turbine.

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Here, it isn't steam but a waterfall that powers it.

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Its cupped rotor system, similar to those of the traditional watermill

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was designed and adapted to power production par the american Lester Allan

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Pelton in 1879. Since, it has been used by a number of modern hydropower plants.

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This double wheel turbine, built in 1926 by Arlod, was set up

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in Savoie below the 174m (571ft) high Perrière waterfall near Vignotan.

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At its max capacity, it's close to 19 400 kW produced by its

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alternator!

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During the 20th century, electricity became trivialized.

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Difficult today to find the aura of mystery that surrounded the fairy in the beginning.

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From the performance halls, it went everywhere, even into our kitchens, through

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appliances. For, and we tend to forget it, it's thanks to electricity

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that we mastered cold: without it, no fridges. The very first

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refrigerated cabinets, very costly, were secured to the ground. Then

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in the 20's, models from the USA became more compact, like General Motors

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famous "Frigidaire", a brand that is almost a generic term like

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Scotch tape of Velcro. Here is a model from 1932

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called Frigeco and fabricated by Edison's firm, General

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Electric, for the french market. The spherical cooling system,

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is now at the top of the appliance. In 1956,

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we are closer to a familiar design, some brands even

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allow a few excentricities like this "radiofridge" model from Philips.

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The certainty to get fresh news! Except that with no antenna

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you often have to keep the door open to get a signal! Not the

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greatest idea, but innovation also comes with these kind of wrong good ideas....

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After the cold, heat!

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Here is the ancestor of electrical heating, the Paz & Silva lamp heater from 1910.

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Esthetically pleasing, it hardly heats and does it badly. Usage of lamps

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before the creation of resistances, made it fragile and expensive.

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Resistances can be found in this

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lovely glass heater cleverly named "Radiaglass" by Saint-Gobin manufactury!

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And here are finaly a set of objects that will really make a splash:

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the television set. In 1936,

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the cathode-ray tube (CRT) is so long that the set

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must be vertical and only the foldable miror allowed to see the image straight on.

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Here again, technology evolves very quickly and in 1957, TV's already

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look like those from our childhood, like this model

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Teleavia whose design was inspired by the space exploration. Its robotic look

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isn't surprising when you know that its manufacturer, Sud-Aviation, also made the Concorde.

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Strange and historical objects like these ones, you'll discover plenty more

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in the EDF Electropolis Museum in Mulhouse, and the exploration of electricity's history

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that the museum offers will "cast a new light" on this natural phenomenon

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which brought us so much but that we too often take for granted. It's the time

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to realise how much electricity is the heart of our modern world

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and what would lose if, like Barjavel in his novel "Ashes, Ashes" ,

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we were suddenly without. So, it you have the opportunity, don't

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hesitate to come here, in Mulhouse, to walk beside the electrical fairy and its history! Thanks to EDF for sponsoring this episode.

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If you liked this episode, subscribe, share and give it a blue thumb and comment as well if you wish.

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See you next time for a new episode. Bye!