Apparatus for endothermic process with improved outer burners arrangement

The invention claimed is: 1. A furnace configured to perform an endothermic process, the furnace comprising: tubes containing catalyst for converting gaseous feed, wherein the tubes are positioned inside the furnace in rows parallel to refractory walls along an X-axis, burners mounted to a furnace floor, wherein the burners further comprise inner burners being mounted in rows between the rows of tubes and outer burners being mounted in rows between the rows of tubes and the wall along the X-axis, and close to said wall along the X-axis, wherein the outer burners are positioned such that a distance between the outer burner and the wall along the X-axis (“B2W”) is smaller than or equal to an equivalent burner nozzle diameter (“øb”) of said outer burner (B2W/øb≤1), with said equivalent burner nozzle diameter being equal to a diameter of a disk, which area is a sum of an area of nozzles for air injection of the burner in a case of complex air injection geometry or a maximum size of an air nozzle in a direction perpendicular to the wall along the X-axis in a case of circular or a quadrilateral burner geometry, wherein B2W/øb≥0.60 so as to prevent overheat of the refractory wall by more than 50° C. 2. The furnace according to claim 1 , wherein if the furnace is configured to be used at feed loads lower than 50% of nominal load: B2W/øb≤0.8. 3. The furnace according to claim 1 , wherein if the furnace is configured to be used at loads higher than 50% of nominal load: 0.6≤B2W/øb≤1, so as to prevent overheat of the refractory wall by more than 50° C. 4. An endothermic process to be performed in a furnace, said process comprising the steps of: introducing a gaseous feed and steam to tubes containing catalyst configured to convert the gaseous feed, wherein the tubes are positioned inside the furnace in rows parallel to refractory walls along an X-axis, combusting a fuel in the presence of an oxidant in burners that are mounted to a furnace floor, wherein the burners further comprise inner burners being mounted in rows between the rows of tubes and outer burners being mounted in rows between rows of tubes and the wall along the X-axis, and close to said wall along the X-axis, discharging products generated in the tubes, wherein the outer burners are positioned such that the distance (“B2W”) between the outer burner and the wall along the X-axis is smaller than or equal to an equivalent burner nozzle diameter (“øb”) of said outer burner (B2W/øb≤1), with said equivalent burner nozzle diameter being equal to a diameter of a disk, which area is a sum of an area of a nozzle for air injection of the burner in a case of complex air injection geometry or a maximum size of an air nozzle in a direction perpendicular to the wall along the X-axis in a case of circular or a quadrilateral burner geometry, wherein B2W/øb≥0.60 so as to prevent overheat of the refractory wall by more than 50° C. 5. The endothermic process as claimed in claim 4 , wherein the endothermic process is steam methane reforming. 6. The endothermic process as claimed in claim 4 , wherein if the furnace is configured to be used at feed loads lower than 50% of nominal load: B2W/øb≤0.8. 7. The endothermic process as claimed in claim 4 , wherein if the furnace is configured to be used at loads higher than 50% of nominal load: 0.6≤B2W/øb≤1, so as to prevent overheat of the refractory wall by more than 50° C.