Reformer furnace for performing an endothermic process

What is claimed is: 1. A reformer furnace for performing an endothermic process, comprising a reaction space, a firing space and a flue gas channel in fluid connection with the firing space; wherein the reaction space is formed by a plurality of vertical reaction tubes passing through the firing space, wherein the reaction tubes comprise in the tube interior a catalyst for converting a gaseous input material, wherein the reaction tubes are arranged in line and form one or more reaction tube rows; and wherein the firing space is formed by a plurality of refractory walls, comprises a first end face and a second end face and the firing space comprises a plurality of burners arranged at the first end face which produce flames oriented in the direction of the second end face, wherein the burners are arranged in line and form a plurality of burner rows, wherein a burner row for firing the reaction tubes is arranged parallel to a reaction tube row; and wherein the flue gas channel for withdrawing burner offgases is arranged in the region of the second end face of the firing space and runs parallel to the burner rows and outside the firing space, wherein the flue gas channel has a transition region and a withdrawal region, wherein the flue gas channel is connected to the second end face of the firing space via the transition region and the transition region of the flue gas channel has a reduced channel diameter compared to the withdrawal region of the flue gas channel, and is thus configured to produce a pressure barrier and decouple the firing space from the withdrawal region and configured to produce a uniform flowrate upon removal from the firing space, and wherein each flue gas channel withdraws offgasses from three burner rows and two reaction tube rows. 2. The reformer furnace according to claim 1 , wherein the ratio of the channel diameter of the transition region to the channel diameter of the withdrawal region is 1:2 to 1:10. 3. The reformer furnace according to claim 1 , wherein the smallest channel diameter of the transition region is smaller than the largest channel diameter of the withdrawal region. 4. The reformer furnace according to claim 1 , wherein the channel diameter of the transition region narrows from the second end face of the firing space in the direction of the withdrawal region. 5. The reformer furnace according to claim 4 , wherein the channel diameter of the transition region narrows from the second end face of the firing space in the direction of the withdrawal region and subsequently widens in the direction of the withdrawal region. 6. The reformer furnace according to claim 5 , wherein the channel diameter of the transition region narrows from the second end face of the firing space in the direction of the withdrawal region, subsequently has a constant diameter and subsequently widens in the direction of the withdrawal region. 7. The reformer furnace according to claim 1 , wherein the withdrawal region of the flue gas channel has a constant diameter and/or a constant height over the entire channel length. 8. The reformer furnace according to claim 1 , wherein the flue gas channel is in the form of a one-piece construction, wherein the transition region and the withdrawal region of the flue gas channel are joined to one another with a mechanical or atomic-level join. 9. The reformer furnace according to claim 1 , wherein no cover slabs provided with means of burner offgas entry in the form of slots, holes, swirl plates or gaps, are provided between the withdrawal region of the flue gas channel and the second end face of the firing space. 10. The reformer furnace according to claim 1 , wherein the first end face of the firing space and the burners are arranged at the bottom and the second end face of the firing space and the flue gas channel are arranged at the top, wherein the burners produce upwardly oriented flames. 11. The reformer furnace according to claim 10 , wherein a feed for the gaseous input material and a discharge for the reaction product of the endothermic process are each arranged at the bottom end of a reaction tube. 12. The reformer furnace according to claim 1 , wherein the ratio of the height of the transition region to the height of the withdrawal region of the flue gas channel is 1:1 to 5:1.