A system for the drying of exhaust gases from a fuel cell system includes two heat exchangers alternately exposed to an exhaust gas, which ice and accumulate water vapour from the exhaust gas by cooling through a coolant. A valve arrangement with a number of valves is adapted in such a manner that i
A system for the drying of exhaust gases from a fuel cell system includes two heat exchangers alternately exposed to an exhaust gas, which ice and accumulate water vapour from the exhaust gas by cooling through a coolant. A valve arrangement with a number of valves is adapted in such a manner that it operates one of the heat exchangers in an icing phase, in which the icing of water vapour is conducted, and the other heat exchanger in a regeneration phase, in which the accumulated ice melts and is extracted, in an alternating manner. This system is especially suitable in aircraft for drying an oxygen depleted exhaust gas from a fuel cell system for inerting a tank.
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1. A system for drying of exhaust gases from a fuel cell system, comprising: at least one first heat exchanger;at least one second heat exchanger;a common exhaust gas inlet and a common exhaust gas outlet for the first and second heat exchangers;a common coolant inlet and a common coolant outlet for
1. A system for drying of exhaust gases from a fuel cell system, comprising: at least one first heat exchanger;at least one second heat exchanger;a common exhaust gas inlet and a common exhaust gas outlet for the first and second heat exchangers;a common coolant inlet and a common coolant outlet for the first and second heat exchangers;a common air outlet for the first and second heat exchangers;a valve arrangement with a plurality of valves; andat least one condensate extractor for extracting condensate;wherein the valve arrangement is adapted for operating either the first heat exchanger or the second heat exchanger in an icing phase and for operating the respective other heat exchanger in a regeneration phase;wherein in the icing phase a first part of a flow of exhaust gas into the common exhaust gas inlet and out of the common exhaust gas outlet and a flow of coolant into the common coolant inlet and out of the common coolant outlet flow through the respective heat exchanger in order to ice water vapour contained in the exhaust gas; andwherein in the regeneration phase a second part of the exhaust gas flows out of the common exhaust gas inlet through the respective heat exchanger to the common air outlet and thereby thaws the ice formed in the respective heat exchanger, subsequently extracting the thawed ice through the condensate extractor. 2. The system according to claim 1, wherein the common coolant inlet is connected to a cryogenic hydrogen tank . 3. The system according to claim 1, wherein the common coolant outlet is connected to a cryogenic hydrogen tank . 4. The system according to claim 1, wherein the common exhaust gas outlet is connected to a fuel tank for inerting the free volume of the tank. 5. The system according to claim 1, further comprising a processing unit connected to the plurality of valves, and adapted in such a manner that the valves are so controlled that the first heat exchanger and the second heat exchanger are operated alternately in an icing phase and a regeneration phase. 6. The system according to claim 5, wherein the processing unit, on the basis of first and second characteristic icing curves of the first heat exchanger and the second heat exchanger, respectively, automatically determines a favourable time for the activation of the plurality of valves in relation to surrounding conditions. 7. The system according to claim 6, wherein the first heat exchanger and the second heat exchanger comprise a first and second sensor to determine the respective degrees of icing and/or temperatures of the first and second heat exchangers, said first and second sensors being connected to the processing unit to determine a favourable time for the activation of the plurality of valves. 8. The system according to claim 1, further comprising a third heat exchanger with a third coolant inlet, a third coolant outlet, a third exhaust gas inlet and a third exhaust gas outlet, wherein the third coolant inlet is connected to the common coolant outlet of the first heat exchanger and the second heat exchanger and wherein the third exhaust gas outlet is connected to the common exhaust gas inlet of the first heat exchanger and the second heat exchanger. 9. The system according to claim 8, wherein the third coolant outlet is configured so as to be connectable to a fuel inlet of a fuel cell system. 10. The system according to claim 8, comprising a fourth heat exchanger with a fourth coolant inlet, a fourth coolant outlet, a fourth exhaust gas inlet and a fourth exhaust gas outlet, wherein the fourth coolant inlet is connected to the common coolant outlet of the first heat exchanger and the second heat exchanger and wherein the fourth exhaust gas outlet is connected to the third exhaust gas inlet. 11. A method for drying of exhaust gases from a fuel cell system, comprising: introducing a first part of exhaust gas from the fuel cell system into a first heat exchanger and exposing the first heat exchanger to a coolant for icing water vapour contained in the exhaust gas;reducing the first part of the exhaust gas introduced into the first heat exchanger and interrupting the exposure to the coolant for thawing the accumulated condensate ice and extracting the condensate by at least one condensate extractor;introducing a second part of the exhaust gas from the fuel cell system into a second heat exchanger and exposing the first heat exchanger to a coolant for icing water vapour contained in the exhaust gas; andreducing the second part of the exhaust gas introduced into the second heat exchanger and interrupting the exposure to the coolant for thawing the ice and extracting of the thawed ice by the condensate extractor. 12. The method according to claim 11, wherein the steps are carried out continuously in sequence, wherein, if the process is carried out continuously, the introduction of the exhaust gas is achieved by increasing the exhaust gas flow. 13. The method according to claim 11, wherein hydrogen with a temperature in a range of the hydrogen boiling point is used as a coolant from a cryogenic hydrogen tank. 14. An aircraft comprising at least one fuel cell system, at least one cryogenic hydrogen tank and at least one system for the drying of exhaust fuels from the fuel cell system, comprising: at least one first heat exchanger;at least one second heat exchanger;a common exhaust gas inlet and a common exhaust gas outlet for the first and second heat exchangers;a common coolant inlet and a common coolant outlet for the first and second heat exchangers;a common air outlet for the first and second heat exchangers;a valve arrangement with a plurality of valves; andat least one condensate extractor for extracting condensate;wherein the valve arrangement is adapted for operating either the first heat exchanger or the second heat exchanger in an icing phase and for operating the respective other heat exchanger in a regeneration phase;wherein in the icing phase a first part of a flow of exhaust gas into the common exhaust gas inlet and out of the common exhaust gas outlet and a flow of coolant into the common coolant inlet and out of the common coolant outlet flow through the respective heat exchanger in order to ice water vapour contained in the exhaust gas; andwherein in the regeneration phase a second part of the exhaust gas flows out of the common exhaust gas inlet through the respective heat exchanger to the common air outlet and thereby thaws the ice formed in the respective heat exchanger, subsequently extracting the thawed ice through the condensate extractor.
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