METHOD OF INTEGRATING A FUEL CELL WITH A STEAM METHANE REFORMER

Abstract

A method of integrating a fuel cell with a steam methane reformer is provided. The system includes at least one fuel cell including an anode and a cathode, and a steam methane reformer including a syngas stream, and a flue gas stream. The method includes introducing at least a portion of the flue gas stream to the cathode, thereby producing a CO2 depleted flue gas stream and introducing a hydrocarbon containing stream to the anode, thereby producing an electrical energy output and a carbon dioxide and hydrogen containing stream from the fuel cell.

Claims

1. A method of integrating a fuel cell with a steam methane reformer, comprising: at least one fuel cell 100 comprising an anode 104 and a cathode 103, a steam methane reformer 114 comprising a syngas stream 305, and a flue gas stream 101, the method comprising: a) introducing at least a portion of the flue gas stream 101 to the cathode 103, thereby producing a CO2 depleted flue gas stream 112 b) introducing a hydrocarbon containing stream 303 to the anode 104, thereby producing an electrical energy output 107 and a carbon dioxide and hydrogen containing stream 307 from the fuel cell 100, c) separating a hydrogen-rich stream 306 from the carbon dioxide and hydrogen containing stream 307, thereby producing a carbon dioxide rich stream 111, d) combining the hydrogen-rich stream 306 with the syngas stream 305, thereby producing a combined syngas stream, and e) introducing the combined syngas stream into a hydrogen separation device 115, thereby producing a second high purity hydrogen stream 116.

2. The method of claim 1, wherein the hydrocarbon containing stream 303 is natural gas.

3. The method of claim 1, wherein the hydrocarbon containing stream is desulfurized prior to introduction into the anode 104.

4. The method of claim 1, wherein the carbon dioxide and hydrogen containing stream 307 passes through a water-gas shift reactor 108 between steps b) and c).

5. The method of claim 1, wherein the syngas stream 305 has passed through a water-gas shift reactor 108 prior to step d).

6. A method of integrating a fuel cell with a steam methane reformer, comprising: at least one fuel cell 100 comprising an anode 104 and a cathode 103, a steam methane reformer 114 comprising a syngas stream 305, and a flue gas stream 101, the method comprising: a) introducing at least a portion of the flue gas stream 101 to the cathode 103, thereby producing a CO2 depleted flue gas stream 112 b) introducing a hydrocarbon containing stream 303 to the anode 104, thereby producing an electrical energy output 107 and a carbon dioxide and hydrogen containing stream 307 from the fuel cell 100, c) introducing at least a portion of syngas stream 305 into a hydrogen separation device 115, thereby producing a high purity hydrogen stream 116, d) separating a hydrogen-rich stream 306 from the carbon dioxide and hydrogen containing stream 307, thereby producing a carbon dioxide rich stream 111, and e) introducing the hydrogen-rich stream 306 into a second hydrogen separation device 401, thereby producing a second high purity hydrogen stream 402.

7. The method of claim 6, wherein the hydrocarbon containing stream 303 is natural gas.

8. The method of claim 6, wherein the hydrocarbon containing stream is desulfurized prior to introduction into the anode 104.

9. The method of claim 6, wherein the carbon dioxide and hydrogen containing stream 307 passes through a water-gas shift reactor 108 between steps b) and d).

10. The method of claim 6, wherein the syngas stream 305 passes through a water-gas shift reactor 108 prior to step c).

11. A method of integrating a fuel cell with a steam methane reformer, comprising: at least one fuel cell 100 comprising an anode 104 and a cathode 103, a steam methane reformer 114 comprising a syngas stream 304, and a flue gas stream 101, the method comprising: a) introducing at least a portion of the flue gas stream 101 to the cathode 103, thereby producing a CO2 depleted flue gas stream 112 b) introducing a hydrocarbon containing stream 303 to the anode 104, thereby producing an electrical energy output 107 and a carbon dioxide and hydrogen containing stream 502 from the fuel cell 100, c) combining at least a portion of the carbon dioxide and hydrogen containing stream 502 with the syngas stream 304, thereby producing a combined syngas stream, d) separating a hydrogen-rich stream 306 from the combined syngas stream, thereby producing a carbon dioxide rich stream 111, and e) introducing the hydrogen-rich stream 306 into a hydrogen separation device 115, thereby producing a high purity hydrogen stream 116.

12. The method of claim 11, wherein the hydrocarbon containing stream 303 is natural gas.

13. The method of claim 11, wherein the hydrocarbon containing stream is desulfurized prior to introduction into the anode 104.

14. The method of claim 11, wherein the combined syngas stream passes through a water-gas shift reactor 108 between step c) and step d).

15.-18. (canceled)

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] For a further understanding of the nature and objects for the present invention, reference should be made to the following detailed description, taken in conjunction with the accompanying drawings, in which like elements are given the same or analogous reference numbers and wherein:

[0011] FIG. 1 is a schematic representation of a typical fuel cell system as known to the art.

[0012] FIG. 2 is simplified drawing illustrating the basic design in accordance with one embodiment of the present invention.

[0013] FIG. 3 is a schematic representation of one embodiment in accordance with one embodiment of the present invention.

[0014] FIG. 4 is a schematic representation of another embodiment in accordance with one embodiment of the present invention.

[0015] FIG. 5 is a schematic representation of another embodiment in accordance with one embodiment of the present invention.

[0016] FIG. 6 is a schematic representation of another embodiment in accordance with one embodiment of the present invention.

ELEMENT NUMBERS

[0017] 100=fuel cell [0018] 101=flue gas stream [0019] 102=oxidizer (optional) [0020] 103=fuel cell cathode [0021] 104=fuel cell anode [0022] 105=natural gas stream [0023] 106=desulfurizer (optional) [0024] 107=electrical production from fuel cell [0025] 108=water-gas shift converter [0026] 109=compressor [0027] 110=carbon dioxide/hydrogen separation unit [0028] 111=high purity carbon dioxide stream [0029] 112=CO2-depleted flue gas stream [0030] 113=steam methane reformer burners [0031] 114=steam methane reformer [0032] 115=pressure swing adsorption unit [0033] 116=high purity hydrogen stream [0034] 117=tail gas (from pressure swing adsorption unit) [0035] 301=natural gas stream to SMR burners [0036] 302=natural gas stream to SMR (process stream) [0037] 303=natural gas stream to fuel cell anode [0038] 304=raw syngas stream (from SMR) [0039] 305=shifted syngas stream (from water-gas shift converter) [0040] 306=hydrogen-rich stream (from carbon dioxide/hydrogen separation unit) [0041] 307=CO2-rich stream (from fuel cell anode) [0042] 308=shifted CO2-rich stream (from fuel cell anode) [0043] 401=second pressure swing adsorption unit [0044] 402=second high purity hydrogen stream (from second pressure swing adsorption unit) [0045] 501=compressed, non-shifted stream (from fuel cell anode)

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0046] The integration of a fuel cell system with the flue gas of a coal or natural gas power plant has already been studied extensively. Typically, after a first purification step to remove harmful impurities for the fuel cell such as sulfur compounds or halides, the flue gas is preheated in an oxidizer before entering the cathode.

[0047] The O.sub.2 and the CO.sub.2 present in the flue gas stream will be reduced into ions CO.sub.3.sup.2− following the reaction:

1/2O.sub.2+CO.sub.2+2e−=CO.sub.3.sup.2−

[0048] The ions CO.sub.3.sup.2− will be transferred to the anode side via the electrolyte. On the anode side, natural gas is injected with steam so that a reforming reaction will happen:

CH.sub.4+H.sub.2O=CO+3H.sub.2

[0049] The H2 produced will then react with the CO.sub.3.sup.2− ions via the following reaction:

H.sub.2+CO.sub.3.sup.2−=CO.sub.2+H.sub.2O+2e−

[0050] Referring to FIG. 1, a typical fuel cell system design is illustrated. As disclosed in, for example, U.S. Pat. Nos. 7,396,603; 7,060,382, and Japanese Patent 61085773, flue gas stream 101, which may be provided by a hydrocarbon-fueled powerplant, is optionally preheated in oxidizer 102, before entering cathode 103, and as discussed above, produces CO.sub.2 depleted flue gas stream 112. CO.sub.2 from the flue gas 101 (in the form of CO.sub.3.sup.2− as discussed above) is transferred to anode 104. Meanwhile, natural gas stream 105 is optionally desulfurized 106, before entering anode 104. Then, by way of the above reactions, the system generates electricity 107. The gas stream exiting the outlet of anode 104 may then be sent to water-gas shift converter 108 to convert the remaining CO and water to H.sub.2 and CO.sub.2. The gas stream exiting the outlet of water-gas shift converter 108 may compressed in compressor 109 and then be sent to CO.sub.2/H.sub.2 separation unit 110 which is typically a cryogenic unit to recover high purity CO.sub.2 stream 111 in a liquid or gaseous phase.

[0051] High purity CO.sub.2 stream 111 may be used for enhanced oil recovery, carbon capture and storage, or even for liquid merchant application after further treatment. If a cryogenic unit is utilized as CO.sub.2/H.sub.2 separation unit 110, there typically will be a purge stream that contains some hydrogen. This stream may be sent back to the anode inlet or is burnt in the oxidizer at the cathode inlet (not shown).

[0052] Referring to FIG. 2, a simplified diagram exemplifying the basic integration of the present invention is illustrated. For convenience and to avoid confusion, and as the overall intent of the instant application is system integration, when applicable, element which serve a common purpose will be indicated with the same element numbers. The present invention is looking at integration improvements between a Steam Methane Reformer (SMR) and a fuel cell system to be implemented on the flue gas of the SMR in order to capture the CO.sub.2. The feedstock considered is natural gas for both the SMR and the fuel cell.

[0053] If there is sufficient sulfur content in the natural gas to be a concern for the fuel cell, it is possible to send the natural gas to be used at the SMR burners 113 and as a feedstock to anode 104 to (optional) desulfurizer 106. If sufficient sulfur is present in the natural gas feed, it will turn into SO.sub.x during the combustion at SMR burners 113 and will thus be present in the SMR flue gas. In case of an integration with a fuel cell, as at least a portion of the natural gas is also used in anode 104, it may be of interest to have a common desulfurization unit 106 with the reforming section of SMR 114, SMR burners 113, and anode 104. It will allow to avoid a costly SOx removal system to be implemented on the SMR flue gas 101 before entering the cathode 103.

[0054] Thus, natural gas stream 105 is (optionally) introduced into desulfurization unit 106. Natural gas stream 105 is split into three streams, one which enters SMR burners 113, one which enters SMR 114 as a process stream, and one which enters fuel cell 100. The syngas stream exiting SMR 114 then enters water-gas shift converter 108, and then pressure swing adsorber (PSA) 115. PSA 115 thereby produces high purity hydrogen stream 116 and tail gas stream 117. Tail gas stream 117, from PSA 115, may be combined with NG stream 105 and used as fuel to SMR burners 113.

[0055] Turning now to FIG. 3, one embodiment of the present invention is provided. Natural gas stream 105 is (optionally) introduced into desulfurization unit 106. Natural gas stream 105 is then split into three streams. Stream 301 enters SMR burners 113, stream 302 enters SMR 114 as a process stream, and stream 303 enters fuel cell anode 104. Raw syngas stream 304 exiting SMR 114 then enters water-gas shift converter 108. Shifted syngas stream 305 is combined with hydrogen-rich stream 306 (discussed below), and the combined stream is introduced into pressure swing adsorber (PSA) 115. PSA 115 thereby produces high purity hydrogen stream 116 and tail gas stream 117. Tail gas stream 117 may be combined with NG stream 301 and used as fuel to SMR burners 113.

[0056] Flue gas stream 101 is introduced into cathode 103 and produces CO.sub.2 depleted flue gas stream 112. CO.sub.2 from the flue gas 101 (in the form of CO.sub.3.sup.2− as discussed above) is transferred to anode 104. Meanwhile, natural gas stream 303 is introduced into anode 104. Fuel cell 100 thus produces electricity 107 and CO.sub.2-rich stream 307. CO.sub.2-rich stream 307 is then sent to water-gas shift converter 108 to convert the remaining CO and water to H.sub.2 and CO.sub.2, thus producing shifted CO.sub.2-rich stream 308. Shifted CO.sub.2-rich stream 308 is then compressed in compressor 109 and then be sent to CO.sub.2/H.sub.2 separation unit 110. CO.sub.2/H.sub.2 separation unit 110 may be any appropriate system known to the art. CO.sub.2/H.sub.2 separation unit 110 may be a cryogenic unit to recover high purity CO.sub.2 stream 111 in a liquid or gaseous phase. If a cryogenic unit is utilized as CO.sub.2/H.sub.2 separation unit 110, there is a H2-rich purge stream 306. As discussed above, H2-rich purge stream 306 is combined with shifted syngas stream 305, and the combined stream is introduced into PSA 115.

[0057] Turning now to FIG. 4, another embodiment of the present invention is provided. Natural gas stream 105 is (optionally) introduced into desulfurization unit 106. Natural gas stream 105 is then split into three streams. Stream 301 enters SMR burners 113, stream 302 enters SMR 114 as a process stream, and stream 303 enters fuel cell 100. Raw syngas stream 304 exiting SMR 114 then enters water-gas shift converter 108. Hydrogen-rich stream 305 is introduced into PSA 115. PSA 115 thereby produces high purity hydrogen stream 116 and tail gas stream 117. Tail gas stream 117 may be combined with NG stream 301 and used as fuel to SMR burners 113.

[0058] Flue gas stream 101 is introduced into cathode 103 and produces CO.sub.2 depleted flue gas stream 112. CO.sub.2 from the flue gas 101 (in the form of CO.sub.3.sup.2− as discussed above) is transferred to anode 104. Meanwhile, natural gas stream 303 is introduced into anode 104. Fuel cell 100 thus produces electricity 107 and CO.sub.2-rich stream 307. CO.sub.2-rich stream 307 is then sent to water-gas shift converter 108 to convert the remaining CO and water to H.sub.2 and CO.sub.2, thus producing shifted CO.sub.2-rich stream 308. Shifted CO.sub.2-rich stream 308 is then compressed in compressor 109 and then be sent to CO.sub.2/H.sub.2 separation unit 110. CO.sub.2/H.sub.2 separation unit 110 may be any appropriate system known to the art. CO.sub.2/H.sub.2 separation unit 110 may be a cryogenic unit to recover high purity CO.sub.2 stream 111 in a liquid or gaseous phase. If a cryogenic unit is utilized as CO.sub.2/H.sub.2 separation unit 110, there is a H2-rich purge stream 306. H2-rich purge stream 306 is introduced into second PSA 401, thus producing second high purity hydrogen stream 402.

[0059] Turning now to FIG. 5, another embodiment of the present invention is provided. Natural gas stream 105 is (optionally) introduced into desulfurization unit 106. Natural gas stream 105 is then split into three streams. Stream 301 enters SMR burners 113, stream 302 enters SMR 114 as a process stream, and stream 303 enters fuel cell 100. Raw syngas stream 304 exiting SMR 114 is combined with compressed CO2-rich stream 502 (discussed below), and the combined stream is introduced into water-gas shift converter 108, thus producing hydrogen-rich stream 305. Hydrogen-rich stream 305 is sent to CO.sub.2/H.sub.2 separation unit 110 which is typically a cryogenic unit to recover high purity CO.sub.2 stream 111 in a liquid or gaseous phase. Other technologies such as amine can be considered for the unit 110. From the CO.sub.2/H.sub.2 separation unit 110, there is a H2-rich purge stream 306. H2-rich purge stream 306 is introduced into PSA 115, thus producing high purity hydrogen stream 116 and tail gas stream 117. Tail gas stream 117 may be combined with NG stream 301 and used as fuel to SMR burners 113.

[0060] Flue gas stream 101 is introduced into cathode 103 and produces CO.sub.2 depleted flue gas stream 112. CO.sub.2 from the flue gas 101 (in the form of CO.sub.3.sup.2− as discussed above) is transferred to anode 104. Meanwhile, natural gas stream 303 is introduced into anode 104. Fuel cell 100 thus produces electricity 107 and CO.sub.2-rich stream 307. CO.sub.2-rich stream 307 is compressed in compressor 109. Compressed CO2-rich stream 502 is then combined with raw syngas stream 304, as discussed above, and the combined stream is sent to water-gas shift converter 108. Stream 502 will be injected between the SMR 114 and the shift 108 where the overall heat integration makes the most sense.

[0061] Turning now to FIG. 6, another embodiment of the present invention is provided. Natural gas stream 105 is (optionally) introduced into desulfurization unit 106. Natural gas stream 105 is then split into three streams. Stream 301 enters SMR burners 113, stream 302 enters SMR 114 as a process stream, and stream 303 enters fuel cell 100. Raw syngas stream 304 exiting SMR 114 is combined with compressed CO2-rich stream 502 (discussed below), and the combined stream is introduced into water-gas shift converter 108, thus producing hydrogen-rich stream 305. Hydrogen-rich stream 305 is combined with hydrogen rich purge stream 601, and the combined stream is introduced into PSA 115, thus producing high purity hydrogen stream 116 and tail gas stream 117. Tail gas stream 117 is introduced into CO.sub.2/H.sub.2 separation unit 110 which is typically a cryogenic unit to recover high purity CO.sub.2 stream 111 in a liquid or gaseous phase. If a cryogenic unit is utilized as CO.sub.2/H.sub.2 separation unit 110, H2-rich purge stream 601 (discussed above) and another purge stream 118 containing other components such as CO, CH4 and water are produced.

[0062] Flue gas stream 101 is introduced into cathode 103 and produces CO.sub.2 depleted flue gas stream 112. CO.sub.2 from the flue gas 101 (in the form of CO.sub.3.sup.2− as discussed above) is transferred to anode 104. Meanwhile, natural gas stream 303 is introduced into anode 104. Fuel cell 100 thus produces electricity 107 and CO.sub.2-rich stream 307. CO.sub.2-rich stream 307 is then sent to compressor 109. Compressed CO2-rich stream 502 is then combined with raw syngas stream 304, as discussed above, and the combined stream is sent to water-gas shift converter 108.

[0063] It will be understood that many additional changes in the details, materials, steps and arrangement of parts, which have been herein described in order to explain the nature of the invention, may be made by those skilled in the art within the principle and scope of the invention as expressed in the appended claims. Thus, the present invention is not intended to be limited to the specific embodiments in the examples given above.