Process for producing direct reduced iron (DRI) utilizing gases derived from coal

What is claimed is: 1. A direct reduction process for producing direct reduced iron (DRI) from particulate iron ores in the form of lumps, pellets or mixtures thereof, utilizing reducing gases produced from solid or liquid fossil fuels, in a reduction reactor having a reduction zone where the particles of iron ore are caused to react with a reducing gas fed to said reduction zone at a temperature in the range from 750° C. to 1100° C., characterized by: heating a first gas stream derived from coal by means of regenerative heaters, where heat is transferred from a previously heated solid material to said gas produced from solid or liquid fossil fuels, at a temperature between 650° C. and 800° C.; causing the resulting hot first gas stream derived from coal to flow into contact with a bed of particles of a material adsorbent of sulfur compounds, outside of said reduction reactor, to form a second gas stream; combining said second gas stream with a third gas stream withdrawn from said reduction reactor from which H 2 O and CO 2 have at least partially been removed for regenerating its reducing potential, forming a fourth gas stream; and feeding said fourth gas stream to said reduction zone of the reduction reactor. 2. A direct reduction process according to claim 1 , wherein said gas produced from solid or liquid fossil fuels is coke oven gas. 3. A direct reduction process according to claim 1 , wherein said material adsorbent of sulfur-compounds is DRI. 4. A direct reduction process according to claim 1 , wherein said material adsorbent of sulfur-compounds contains iron oxides. 5. A direct reduction process according to claim 1 , wherein said material adsorbent of sulfur-compounds contains dolomite. 6. A direct reduction process according to claim 1 , wherein said reducing gas fed to the reduction zone is formed by combination of a gas effluent from a catalytic reformer and a gas produced from coal which has been heated and treated by a sulfur-compounds adsorbent material. 7. A direct reduction process according to claim 6 , wherein said gas produced from coal which has been heated and treated by a sulfur-compounds adsorbent material is combined with gas stream withdrawn from the reduction zone before being fed to the catalytic reformer. 8. A direct reduction process according to claim 1 , wherein said reducing gas fed to the reduction zone comprises a combination of a gas stream effluent from a catalytic reformer, a gas stream produced from coal, which has been heated and treated by contact with a sulfur-compounds adsorbent material, and a gas stream withdrawn from the reduction zone heated to a temperature above 750° C. 9. A direct reduction process according to claim 8 , wherein said gas stream withdrawn from the reduction zone is combined with a gas stream produced from coal, before it is treated by contact with said material adsorbent of sulfur-compounds, and after being treated by contact with said material adsorbent of sulfur-compounds is then combined with a gas stream effluent from the catalytic reformer. 10. A direct reduction process according to claim 1 , wherein BTX contained in the gas stream produced from coal are destroyed by contacting said gas produced from coal with the sulfur-compounds adsorbent material. 11. A direct reduction process for producing direct reduced iron (DRI) from particulate iron ores in the form of lumps, pellets or mixtures thereof, utilizing reducing gases produced from solid or liquid fossil fuels, in a reduction reactor having a reduction zone where the particles of iron ore are caused to react with a reducing gas fed to said reduction zone at a temperature in the range from 750° C. to 1100° C., characterized by: heating a first gas stream derived from coal at a temperature between 650° C. and 800° C.; causing said hot gas derived from coal to flow into contact with a bed of DRI particles to adsorb sulfur compounds therefrom, outside of said reduction reactor, to form a second gas stream; combining said second gas stream with a third gas stream withdrawn from said reduction reactor from which H 2 O and CO 2 have at least partially been removed for regenerating its reducing potential, forming a fourth gas stream; and feeding said fourth gas stream to said reduction zone of the reduction reactor. 12. A direct reduction process according to claim 11 , wherein said gas produced from solid or liquid fossil fuels is coke oven gas. 13. A direct reduction process according to claims 12 , wherein BTX contained in the gas stream produced from coal are destroyed by contacting said gas produced from coal with bed of DRI. 14. A direct reduction process according to claim 11 , wherein said reducing gas fed to the reduction zone is formed by combination of a gas effluent from a catalytic reformer and a gas produced from coal which has been heated and treated by a bed of DRI. 15. A direct reduction process according to claim 14 , wherein said gas produced from coal which has been heated and treated by a bed of DRI is combined with gas stream withdrawn from the reduction zone before being fed to the catalytic reformer. 16. A direct reduction process according to claim 11 , wherein said reducing gas fed to the reduction zone comprises a combination of a gas stream effluent from a catalytic reformer, a gas stream produced from coal, which has been heated and treated by contact with a bed of DRI, and a gas stream withdrawn from the reduction zone heated to a temperature above 750° C. 17. A direct reduction process according to claim 16 , wherein said gas stream withdrawn from the reduction zone is combined with a gas stream produced from coal, before it is treated by contact with a bed of DRI, and after such treatment is combined with a gas stream effluent from the catalytic reformer. 18. A plant for producing direct reduced iron (DRI) from particulate iron ores in the form of lumps, pellets or mixtures thereof, comprising a reduction reactor having a reduction zone where the particles or iron ore are caused to react with a reducing gas fed to said reduction zone at a temperature in the range from 750° C. to 1100° C., characterized by further comprising: a plurality of gas heaters for heating a gas stream produced from coal at a temperature between 650° C. and 800° C.; at least two vessels each containing a bed of particles of a material capable of adsorbing sulfur-compounds contained in said gas produced from coal and which operate alternating an adsorption cycle and a cycle for discharge and charge of said material; joinder piping for combining flow from said two vessels with flow derived from said reactor so as to combine the gas produced from coal, free from sulfur-compounds, with a reducing gas stream withdrawn from the reduction reactor, from which H 2 O and CO 2 have been at least partially removed to regenerate its reducing potential; and feed piping for introducing at least the resulting combination of gases to the reduction zone of said reactor. 19. A plant for producing direct reduced iron (DRI) from particulate iron ores according to claim 18 , further characterized by the fact that the gas heaters for heating said gas produced from coal are regenerative, where in alternate operation cycles, a refractory material accumulates heat produced by the combustion of a fuel in a first stage of the cycle and then this heat is transferred to said gas produced from coal in a second stage of the gas heating cycle. 20. A plant for producing direct reduced iron (DRI) from particulate iron ores according to