The
war of the currents was won by alternating current because transmission of power at high voltage could use
transformers to easily convert between voltages.
Marcel Deprez explored early transmission using
direct current but avoiding transformers by placing generators and loads in series Like Brush's dynamos, current is kept constant, and when increasing load demands more pressure, voltage is increased. In 1889, the system was first put into service in
Italy by the
Acquedotto de Ferrari-Galliera company. Earlier the company had built a water supply for Genoa from the Gorzente River, and were interested whether turbines for electrical generation might address their long standing problem of reducing excess pressure. The first turbine of was installed at Galvani station, which turned the two Thury 6-pole dynamos that each produce 1000 to 1100 volts at 45 amperes. In order to keep the same current, their speed varies from 20 to 475 rpm, regulated by changing the flow through the water turbine. The circuit supplied 15 motors along the line stretching to Genoa, including a motor at the railway station, and motor transformers at Central Electric Lighting Station in Genoa. Additional generation plants followed providing lighting as well as motive power to a number of mills, factories and railway repair shops. An example of the mechanical voltage conversion employed was described for the lighting of Sampierdarena Train Station. The Thury system powered a motor which drove via belts twelve Siemens and two Technomasio dynamos for the station's lights. Genoa's Thury system was progressively upgraded to transmit 630 kW at 14 kV DC over a circuit distance of 120 km, using later dynamos capable of producing 2.5 megawatts (5000 volts at 500 amperes) using double
commutators to reduce the voltage on each commutator. Thury systems were installed over the next few years at several sites: • 1889 first station at 6 kV supplying Genoa from Gorzente River hydro turbines. • 1897 in La Chaux-de-Fonds (14 kV) • 1899 between St-Maurice and Lausanne (22 kV, 3.7 megawatts) • 1906
Lyon-Moutiers project (final capacity: 20 megawatts, 125 kV, 230 km) • 1911 Metropolitan Electric Supply Company, London, 100-ampere 5,000-volt generators The
Moutiers-Lyon system transmitted 20 megawatts of hydroelectric power a distance of , including 6 miles (10 km) of underground cable. The system used eight series-connected generators with dual commutators for a total voltage of 150,000 volts between the poles. The system was steadily upgraded from 4.3 to 20 MW and ran from about 1906 until 1936. By 1913, fifteen Thury systems were in use in England, Hungary, Russia, Switzerland, France and Italy. Thury systems operated up to the 1930s, but the rotating conversion machinery required high maintenance and had high energy loss. The main limitations of the Thury system was that series distribution meant greater opportunity for power failures. Placing loads in series means that since current must flow through each device to get to the next, if the circuit is broken in any of the devices, the current stops at all other loads. Such series distribution was possible with automatic short circuiting mechanisms as in the
Thomson-Houston and Brush high voltage DC arc light systems, but since each load is not independent as in modern parallel distribution, the approach was inherently more fragile. Attention was turned to conversion of DC to lower voltages that was more efficient and less cumbersome that mechanically driving smaller generators as in the Sampierdarena Railway station example. This was a challenge for all DC systems because the induction principle used in the step down transformers pioneered by
Lucien Gaulard and
ZBD in the early 1880s only worked with AC. Not until grid controlled
mercury arc valves became available for power transmission during the period 1920 to 1940 was it possible to utilize high-voltage direct current for large transmission projects, but by that time AC transmission was dominant, cheap and reliable. == Realized Thury systems ==