Direct current electric arc furnace for metallurgical plant

1 . A direct current electric arc furnace for metallurgical plant comprising at least one bottom electrode having a plurality of metal bars parallel to one another and defining respective longitudinal axes, and a support flange adapted to support and electrically supply said metal bars, wherein each metal bar comprises at least a first portion which includes a first end of the bar, and at least a second portion which is axially adjacent to said first portion and which includes a second end of the bar, said first portion being restrained to said support flange at the first end, and having greater thermal conductivity with respect to said second portion. 2 . The furnace according to claim 1 , wherein said support flange comprises at least a first plate crossed by the metal bars and distal from the first ends of the bars, and at least a second plate proximal to the first ends, the first plate and the second plate being substantially flat and parallel, and arranged so as to form a gap between one another, and wherein each first end is fixed to the second plate. 3 . The furnace according to claim 2 , wherein said second plate is made of bimetallic sheet formed by a first layer, made of a first metal material, and of a second layer, adjacent to the first layer and made of a second metal material, and wherein said second metal material has greater electrical conductivity than the first metal material. 4 . The furnace according to claim 3 , wherein said support flange is provided with a metal conduit, which is fixed below the second plate and communicating with gap for the passage of a cooling fluid. 5 . The furnace according to claim 3 , wherein said support flange is provided with a plurality of electrical contacts arranged at respective peripheral positions of the second plate and adapted to he connected to a power supply source. 6 . The furnace according to claim 4 , wherein said metal conduit is adapted to be connected to a power supply source for distributing electric current to the second plate. 7 . The furnace according to claim 5 , wherein the second layer is divided into a plurality of sectors, preferably by means of a plurality of radial channels, so that each sector is electrically supplied by a respective electrical contact. 8 . The furnace according to claim 1 , wherein the first portion and the second portion have circular section, and the diameter of the first portion is greater than or equal to the diameter of the second portion. 9 . The furnace according to claim 8 , wherein, in the ease of the first portion having diameter greater than the second portion, there are provided annular grooves on a stretch of the first portion arranged inside the gap. 10 . The furnace according to claim 1 , wherein the length of the first portion is greater than or equal to the length of the second portion. 11 . The furnace according to claim 1 , wherein there are provided at least one hundred metal bars in said at least one bottom electrode. 12 . The furnace according to claim 1 , wherein the first portion is made of copper or copper alloy and the second portion is made of steel. 13 . The furnace according to claim 3 , wherein the first metal material is steel and the second metal material is copper or copper alloy. 14 . The furnace according to claim 1 , wherein the metal bars are incorporated in a base sole of the furnace, made of refractory material and arranged above said support flange. 15 . The furnace according to claim 6 , wherein the second layer is divided into a plurality of sectors, preferably by means of a plurality of radial channels, so that each sector is electrically supplied by said metal conduit.