Electrolysis cell, electrolyzer and method for reducing co2

1 .- 24 . (canceled) 25 . An electrolysis cell for the electrochemical reaction of CO 2 on an industrial scale, comprising at least a cathode half shell having a cathode, having a gas space connected to a first gas feed conduit for carbon dioxide gas and to a first gas discharge conduit for gaseous reaction products, in particular carbon monoxide, hydrogen and unreacted carbon dioxide gas, and having a catholyte inlet and a catholyte outlet, and further comprising an anode half shell and a separator arranged between anode half shell and cathode half shell for separating anode space and cathode space, where the anode half shell is provided with at least a second gas discharge conduit for the anode reaction product, in particular oxygen and possibly carbon dioxide, an anolyte inlet and an anolyte outlet and also an anode, and further comprising electric power leads for connecting anode and cathode to a DC voltage source, wherein the cathode is configured as gas diffusion electrode for reacting carbon dioxide gas and cathode, anode and the separator are arranged vertically in their main extension and a gap for passage of the catholyte according to the principle of a falling liquid film is arranged between separator and cathode. 26 . The electrolysis cell as claimed in claim 25 , wherein the separator is an ion exchange membrane or a diaphragm, preferably an ion exchange membrane. 27 . The electrolysis cell as claimed in claim 25 , wherein the vertical main extension of the cathode is at least 30 cm, preferably at least 60 cm, particularly preferably at least 100 cm. 28 . The electrolysis cell as claimed in claim 25 , wherein the cathode is configured as gas diffusion electrode based on silver and/or silver oxide, preferably silver particles, as electrocatalyst and having a pulverulent fluoropolymer, in particular PTFE powder, as nonconductive binder compacted on a metallic or nonmetallic, conductive or nonconductive support. 29 . The electrolysis cell as claimed in claim 25 , wherein the first gas discharge conduit is connected to the upper end of the anode space and the second gas discharge conduit is connected to the upper end of the gas space and the first gas feed conduit is connected to the lower end of the gas space. 30 . The electrolysis cell as claimed in claim 25 , wherein the second gas discharge conduit for the anode reaction product is connected to a second gas separation unit for separating carbon dioxide from oxygen and the second gas separation unit is connected via a carbon dioxide conduit, and optionally via a distributor tube conduit, to the gas feed conduit. 31 . The electrolysis cell as claimed in claim 25 , wherein the catholyte is an aqueous solution of alkali metal hydrogencarbonate, preferably potassium hydrogencarbonate, cesium hydrogencarbonate or sodium hydrogencarbonate, particularly preferably potassium hydrogencarbonate. 32 . The electrolysis cell as claimed in claim 25 , wherein the anolyte is an aqueous solution of alkali metal hydrogencarbonate, preferably potassium hydrogencarbonate, cesium hydrogencarbonate or sodium hydrogencarbonate, particularly preferably potassium hydrogencarbonate. 33 . The electrolysis cell as claimed in claim 25 , wherein when the same electrolyte salt is used for anolyte and catholyte, the catholyte outlet is located at the lower end of the gap and the catholyte inlet is located above the gap on the cathode half shell and the catholyte outlet is preferably connected via a collection tube conduit to an electrolyte collection facility in which catholyte from the catholyte outlet and anolyte from the anolyte outlet are combined. 34 . The electrolysis cell as claimed in claim 25 , wherein the first gas discharge conduit is connected, in particular via a collection conduit, to a gas separation unit for separating carbon monoxide, hydrogen and unreacted carbon dioxide gas. 35 . The electrolysis cell as claimed in claim 34 , wherein the gas separation unit has a recirculation conduit for carbon dioxide gas which has been separated off, which recirculation conduit is, in particular, connected via a distributor tube conduit to the first gas feed conduit for carbon dioxide gas. 36 . The electrolysis cell as claimed in claim 34 , wherein the gas separation unit has a discharge conduit for carbon monoxide which has been separated off, which discharge conduit is connected to a chemical production plant for chemical reaction of carbon monoxide. 37 . The electrolysis cell as claimed in claim 34 , wherein the gas separation unit has a discharge conduit for hydrogen which has been separated off, which discharge conduit is connected to a hydrogen pipe network or a dispensing plant for hydrogen. 38 . The electrolysis cell as claimed in claim 25 , wherein a means for slowing the flow of the catholyte stream is provided in the gap. 39 . The electrolysis cell as claimed in claim 38 , wherein the means for slowing the flow is configured as electrically nonconductive, inert sheet-like textile structure. 40 . The electrolysis cell as claimed in claim 25 , wherein the second gas discharge conduit ( 7 ) for the anode reaction product and the anolyte outlet form a unit and are connected to a collection tube conduit in which the gas/liquid separation occurs and is connected, optionally via a gas removal unit, by an anolyte recirculation conduit, optionally via an electrolyte collection facility, to the anolyte inlet. 41 . The electrolysis cell as claimed in claim 25 , wherein the electrolyte recirculation conduit has a feed conduit and mixing unit for mixing in either water or more highly concentrated electrolyte. 42 . The electrolysis cell as claimed in claim 25 , wherein the anode rests on the separator with point-, line- or area-shaped contact positions of the anode. 43 . An electrolyzer for the electrochemical reaction of CO 2 on an industrial scale by the membrane electrolysis process or diaphragm electrolysis process, wherein the electrolyzer has a plurality of electrolysis cells as claimed in claim 25 , which cells are electrically connected to one another in a bipolar manner. 44 . The electrolyzer as claimed in claim 43 , wherein a collector for anolyte, a collector for catholyte, a distributor for anolyte, a distributor for catholyte and a gas distributor for reaction gas and a gas collector for product gases are provided to connect the feed conduits and discharge conduits of the various electrolysis cells. 45 . A process for the electrochemical reaction of CO 2 on an industrial scale by the membrane electrolysis process at a gas diffusion electrode as cathode, wherein the process is carried out in an electrolysis cell as claimed in claim 25 , where the separator is an ion exchange membrane, which comprises the steps: introduction of the catholyte, an aqueous solution containing at least alkali metal hydrogencarbonate, via the catholyte inlet into the gap between ion exchange membrane and cathode, introduction of the anolyte, an aqueous solution containing at least alkali metal hydrogencarbonate, via the anolyte inlet into the anode space, introduction of the carbon dioxide gas stream through the first gas feed conduit into the gas space, setting of the electrolysis voltage at the power leads, discharge of the reacted catholyte at the catholyte outlet, discharge of the anode reaction product consisting of anolyte and product gas, with anolyte being discharged through the anolyte outlet and product gas oxygen and possibly CO