Process and plant for producing a synthesis gas stream with minimum emission of ammonia

What is claimed is: 1 . A process for producing a synthesis gas comprising hydrogen and carbon oxides by steam reforming of a hydrocarbon containing feed stream with steam in a steam reformer, with minimized emissions of ammonia, the process comprising: (a) providing a steam reformer, comprising: (a1) a plurality of catalyst filled reformer tubes with means for introducing the hydrocarbon containing feed stream and steam into the reformer tubes, and means for discharging a crude synthesis gas stream from the reformer tubes; (a2) a reformer furnace with a floor, a ceiling and side walls which form a furnace interior, with the reformer tubes being arranged inside of the furnace interior and being heated by a plurality of burners; (a3) a flue gas duct being arranged in fluid connection to the furnace interior through one of the side walls; (a4) a catalyst unit being arranged inside of the flue gas duct and outside of the furnace interior, the catalyst unit comprising a first catalytic zone active for the selective catalytic reduction of nitrogen oxides with ammonia to nitrogen, and a second catalytic zone active for catalytic oxidation of ammonia to nitrogen oxides; (b) providing the hydrocarbon containing feed stream and a reforming steam stream and introducing the hydrocarbon containing feed stream and the reforming steam stream into the reformer tubes; (c) providing a fuel gas stream and an oxygen containing oxidant stream and introducing the fuel gas stream and the oxygen containing oxidant stream into the burners, combusting the fuel gas stream with the oxygen containing oxidant stream in the burners and thereby heating the reformer tubes and generating a flue gas stream comprising nitrogen oxides; (d) converting the hydrocarbon containing feed stream with the reforming steam stream under steam reforming conditions in the reformer tubes, discharging a crude synthesis gas comprising hydrogen, carbon oxides, unconverted steam, and ammonia from the reformer tubes; (e) discharging the flue gas stream from the furnace interior through the flue gas duct, and routing at least a portion of the flue gas stream through the catalyst unit; (f) cooling the crude synthesis gas stream in at least one cooling apparatus to a temperature below its dew point to form an aqueous condensate stream comprising ammonia, separating and discharging a synthesis gas stream depleted in water and ammonia from the aqueous condensate stream comprising ammonia using a phase separation apparatus; (g) stripping the aqueous condensate stream comprising ammonia with a stripping gas stream in a stripping apparatus, routing out a condensate stream depleted in ammonia from the stripping apparatus, routing out a stripping gas stream enriched in ammonia from the stripping apparatus; (h) introducing at least a portion of the stripping gas stream enriched in ammonia into the flue gas duct at a first injection point provided on the flue gas duct upstream of the catalyst unit; (i) wherein both the at least a portion of the flue gas stream and the at least a portion of the stripping gas stream enriched in ammonia pass through the first catalyst zone and subsequently through the second catalyst zone of the catalyst unit. 2 . The process according to claim 1 , wherein at least a portion of the condensate stream depleted in ammonia, except a purge stream, is used to generate at least a part of the reforming steam stream. 3 . The process according to claim 1 , wherein the first catalyst zone and the second catalyst zone of the catalyst unit comprise at least one catalyst, selected from the group consisting of catalyst beds of particulate catalysts, catalytic wire meshes, honeycomb catalysts, and structured packing catalysts, wherein the catalyst to be used in the first catalyst zone is active for the selective catalytic reduction of nitrogen oxides with ammonia to nitrogen, and the catalyst to be used in the second catalyst zone is active for catalytic oxidation of ammonia to nitrogen oxides. 4 . The process according to claim 1 , wherein the catalyst unit, the second catalyst zone is arranged downstream of the first catalyst zone, with regard to the flow direction of the flue gas. 5 . The process according to claim 1 , wherein all, or a constant portion, of the stripping gas stream enriched in ammonia is introduced into the flue gas duct. 6 . The process according to claim 1 , wherein at least two heat exchangers are arranged in the flue gas duct between the first injection point for the stripping gas stream enriched in ammonia and the catalyst unit. 7 . The process according to claim 1 , wherein the location of the first injection point is selected so that the average temperature of the flue gas inside of the flue gas duct at this location equals 500° C. or below when the reformer furnace is operated. 8 . The process according to claim 1 , wherein additionally a second injection point for the stripping gas stream enriched in ammonia is provided on the flue gas duct upstream of the position of the first injection point, with regard to the flow direction of the flue gas, wherein the location of the second injection point is selected so that the average temperature of the flue gas inside of the flue gas duct at this location equals 400° C. or above when the reformer furnace is operated. 9 . A plant for producing a synthesis gas comprising hydrogen and carbon oxides by steam reforming of a hydrocarbon containing feed stream with steam in a steam reformer, with minimized emissions of ammonia, the plant comprising the following means and apparatuses, arranged in fluid connection with one another: (a) a steam reformer, comprising: (a1) a plurality of catalyst filled reformer tubes with means for introducing the hydrocarbon containing feed stream and steam into the reformer tubes, and means for discharging a crude synthesis gas stream from the reformer tubes; (a2) a reformer furnace with a floor, a ceiling and side walls which form a furnace interior, with the reformer tubes being arranged inside of the furnace interior and being heated by a plurality of burners; (a3) a flue gas duct being arranged in fluid connection to the furnace interior through one of the side walls; (a4) a catalyst unit being arranged inside of the flue gas duct and outside of the furnace interior, the catalyst unit comprising a first catalytic zone active for the selective catalytic reduction of nitrogen oxides with ammonia to nitrogen, and a second catalytic zone active for catalytic oxidation of ammonia to nitrogen oxides; (b) means for providing the hydrocarbon containing feed stream and a reforming steam stream and means for introducing the hydrocarbon containing feed stream and the reforming steam stream into the reformer tubes; (c) means for providing a fuel gas stream and an oxygen containing oxidant stream and introducing the fuel gas stream and the oxygen containing oxidant stream into the burners; (d) means for discharging a crude synthesis gas comprising hydrogen, carbon oxides, unconverted steam, and ammonia from the reformer tubes; (e) means for discharging a flue gas stream from the furnace interior through the flue gas duct, and means for routing at least a portion of the flue gas stream through the catalyst unit; (f) at least one cooling apparatus for cooling the crude synthesis gas stream to a temperature below its dew point to form an aqueous condensate stream comprising ammonia, a phase separation apparatus for separating and discharging a synthesis gas stream depleted in water and ammonia from the aqueous condensate stream comprising ammonia; (g) a stripping apparatus for stripping the aqueous condensate stream comprising ammonia with a stripping gas stream, means f