CN214378520U - Combined CO2Trapped molten carbonate fuel cell system - Google Patents
Combined CO2Trapped molten carbonate fuel cell system Download PDFInfo
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- CN214378520U CN214378520U CN202120533712.5U CN202120533712U CN214378520U CN 214378520 U CN214378520 U CN 214378520U CN 202120533712 U CN202120533712 U CN 202120533712U CN 214378520 U CN214378520 U CN 214378520U
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
Abstract
The utility model discloses a combine CO2A captured molten carbonate fuel cell system belongs to the technical field of fuel cells. Mainly comprises a methanol reforming hydrogen production unit, a first heat exchange unit, a gas-liquid separation unit, a mixing device and CO2The fuel cell system comprises a trapping unit, a second heat exchange unit, a third heat exchange unit and a fuel cell unit. Uses methanol reformed gas as fuel and CO2The capture technology is combined with anode tail gas circulation, so that CO can be improved2The separation efficiency and the fuel utilization rate reduce the power generation cost of the molten carbonate fuel cell, and simultaneously, exhaust waste heat can be utilized to preheat inlet air, so that the thermoelectric comprehensive efficiency of the power generation system of the molten carbonate fuel cell is improved, the power generation cost of the molten carbonate fuel cell is reduced, and the method has a good application prospect.
Description
Technical Field
The utility model belongs to the technical field of fuel cell, concretely relates to combine CO2Trapped molten carbonate fuelA fuel cell system.
Background
The power generation of molten carbonate fuel cell is a method capable of realizing CO2The clean and efficient power generation mode with near zero emission can reduce energy loss caused by Carnot cycle and directly convert chemical energy in fuel into electric energy.
The molten carbonate fuel cell does not use noble metals such as platinum as a catalyst, so 99.99% of pure hydrogen is not required to be used as fuel, and the molten carbonate fuel cell has the characteristic of wide fuel sources. For example, a method of producing hydrogen by reforming methanol and then purifying the hydrogen in the reformed gas to obtain hydrogen-rich gas as the anode fuel of the fuel cell may be used. The reformed methanol gas mainly contains hydrogen and carbon dioxide, but most of the hydrogen separation and purification methods in use in the market at present have the problems of low purification efficiency and the like.
Disclosure of Invention
In order to solve the above problems, an object of the present invention is to provide a method for combining CO2Captured molten carbonate fuel cell system for enhanced CO in methanol reformate gas2The separation efficiency and the fuel utilization rate of the molten carbonate fuel cell reduce the power generation cost of the molten carbonate fuel cell.
The utility model discloses a realize through following technical scheme:
the utility model discloses a combined CO2The captured molten carbonate fuel cell system comprises a methanol reforming hydrogen production unit, a first heat exchange unit, a gas-liquid separation unit, a mixing device and CO2The system comprises a trapping unit, a second heat exchange unit, a third heat exchange unit and a fuel cell unit;
the inlet of the methanol reforming hydrogen production unit is connected with a methanol feeding pipe, the outlet of the methanol reforming hydrogen production unit is connected with the inlet of the mixing device, the outlet of the mixing device is connected with the hot side inlet of the first heat exchange unit, the hot side outlet of the first heat exchange unit is connected with the gas-liquid separation unit, the liquid phase outlet of the gas-liquid separation unit is connected with a condensed water discharge pipe, and the gas phase outlet of the gas-liquid separation unit is connected with the CO discharge pipe2Connection of a capture unit, CO2CO of a capture unit2The outlet of the cold side of the third heat exchange unit is connected with the cold side inlet of the third heat exchange unit, the cold side outlet of the third heat exchange unit is communicated with the air inlet pipe and then is connected with the cathode fuel feed port of the fuel cell unit, the cathode tail gas outlet of the fuel cell unit is connected with the hot side inlet of the third heat exchange unit, and the hot side outlet of the third heat exchange unit is connected with the cathode tail gas discharge pipe; CO 22H of the trap unit2The outlet is connected with a cold side inlet of the second heat exchange unit, a cold side outlet of the second heat exchange unit is connected with an anode fuel feed inlet of the fuel cell unit, an anode tail gas outlet of the fuel cell unit is connected with two branches, one branch is connected with an anode tail gas discharge pipe, the other branch is connected with a hot side inlet of the second heat exchange unit, and a hot side outlet of the second heat exchange unit is connected with an inlet of the mixing device.
Preferably, a compression unit is arranged on a connecting pipeline between the outlet of the hot side of the second heat exchange unit and the inlet of the mixing device.
Preferably, the first heat exchange unit is a gas-liquid type heat exchanger, and the second heat exchange unit and the third heat exchange unit are gas-gas type heat exchangers.
Preferably, two branches connected with an anode tail gas outlet of the fuel cell unit are respectively provided with a flow detection and control device, a pressure sensor is arranged in the fuel cell unit, and the flow detection and control device and the pressure sensor are respectively connected with a control unit of the system.
Preferably, a temperature detection device and an auxiliary heating device are arranged in the fuel cell unit, and the temperature detection device and the auxiliary heating device are respectively connected with a control unit of the system.
Preferably, a condensed water outlet of the gas-liquid separation unit is connected with a cold side inlet of the first heat exchange unit, a temperature detection device is arranged on a connecting pipeline between an outlet of the mixing device and a hot side inlet of the first heat exchange unit, a flow detection and control device is arranged on a connecting pipeline between the condensed water outlet of the gas-liquid separation unit and the cold side inlet of the first heat exchange unit, and the temperature detection device and the flow detection and control device are respectively connected with a control unit of the system.
Preferably, the air is admittedPipe, CO2CO of a capture unit2Outlet connection line and CO2H of the trap unit2And flow detection and control devices are arranged on the outlet connecting pipelines, and all the flow detection and control devices are respectively connected with the control unit of the system.
Preferably, the wall surface in the mixing device is a smooth curved surface, and a flow disturbing part is arranged in the mixing device.
Compared with the prior art, the utility model discloses following profitable technological effect has:
since the conventional proton exchange membrane fuel cell requires 99.99% of hydrogen purity, the fuel processing unit of the cell system purifies the hydrogen in the methanol reformed gas to 99.99% of purity, while the other side gas still contains a large amount of hydrogen and cannot be used as cathode fuel (only evacuation, catalytic combustion, etc.)
The utility model discloses a combine CO2In the trapped molten carbonate fuel cell system, the anode fuel required by the fuel cell unit is hydrogen, and the cathode fuel is carbon dioxide and air, so that the hydrogen and the carbon dioxide generated by the methanol reforming hydrogen production process can be fully utilized as fuels, and the cost of the methanol reforming hydrogen production process is low; binding of subsequent CO2The trapping technology can improve the separation efficiency of the methanol reformed gas and provide fuel with higher purity for the molten carbonate fuel cell. The waste heat of the tail gas is comprehensively utilized, the comprehensive thermoelectric efficiency of the fuel cell power generation system is improved, and the energy consumption of the system is reduced. The anode tail gas with approximate composition is adopted to be circulated and mixed with the methanol reformed gas, the separation and purification of the hydrogen and the carbon dioxide are carried out again, the utilization rate of the fuel is improved, and meanwhile, the anode tail gas is not treated by adopting a catalytic combustion technology, so that the cost is lower.
Furthermore, a compression unit is arranged on a connecting pipeline between a hot side outlet of the second heat exchange unit and an inlet of the mixing device, and the speed and the flow of the circulating tail gas are controlled.
Furthermore, the first heat exchange unit adopts a gas-liquid type heat exchanger, and the second heat exchange unit and the third heat exchange unit adopt gas-gas type heat exchangers, so that the heat exchange efficiency is high, and the waste heat utilization rate is improved.
Furthermore, the proportion of circulation and evacuation of the anode tail gas is adjusted in real time through the pressure value in the fuel cell unit, and the efficiency and the stability of the system can be improved.
Furthermore, the temperature detection device can monitor the temperature in the fuel cell unit in real time, and the working temperature of the fuel cell can be reached or maintained through the auxiliary heating device when necessary, so that the efficiency and the stability of the system are improved.
Furthermore, the condensed water of the gas-liquid separation unit is used for cooling the mixed gas, so that the energy utilization rate is improved, and the energy consumption of the system is reduced.
Further, by introducing CO into the air inlet pipe2CO of a capture unit2Outlet connection line and CO2H of the trap unit2The outlet connecting pipeline is provided with the flow detection and control device, so that the flow of feeding can be adjusted in real time according to the working condition of the system, and the maximum efficiency and the safety stability of the system are ensured.
Furthermore, the wall surface in the mixing device adopts a smooth curved surface, so that the uniform flow of the internal gas is ensured without dead angles, and meanwhile, the turbulence component can improve the mixing degree of the gas.
Drawings
Fig. 1 is a schematic diagram of the overall structure of the system of the present invention.
In the figure: 1-methanol reforming hydrogen production unit; 2-a first heat exchange unit; 3-a gas-liquid separation unit; 4-a mixing device; 5-CO2A trapping unit; 6-a second heat exchange unit; 7-a compression unit; 8-a third heat exchange unit; 9-fuel cell unit.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings, which are included to illustrate and not to limit the present invention:
as shown in figure 1, for the combination of CO of the present invention2The captured molten carbonate fuel cell system comprises a methanol reforming hydrogen production unit 1, a first heat exchange unit 2, a gas-liquid separation unit 3, a mixing device 4 and CO2 A trapping unit 5, a second heat exchange unit 6 and a third heat exchange unit8 and a fuel cell unit 9.
The inlet of the methanol reforming hydrogen production unit 1 is connected with a methanol feeding pipe, the outlet of the methanol reforming hydrogen production unit 1 is connected with the inlet of the mixing device 4, the outlet of the mixing device 4 is connected with the hot side inlet of the first heat exchange unit 2, the hot side outlet of the first heat exchange unit 2 is connected with the gas-liquid separation unit 3, the liquid phase outlet of the gas-liquid separation unit 3 is connected with a condensed water discharge pipe, and the gas phase outlet of the gas-liquid separation unit 3 is connected with the CO discharge pipe2Connection of the capture unit 5, CO2CO of the capture unit 52The outlet is connected with the cold side inlet of the third heat exchange unit 8, the cold side outlet of the third heat exchange unit 8 is communicated with the air inlet pipe and then is connected with the cathode fuel feed inlet of the fuel cell unit 9, the cathode tail gas outlet of the fuel cell unit 9 is connected with the hot side inlet of the third heat exchange unit 8, and the hot side outlet of the third heat exchange unit 8 is connected with the cathode tail gas discharge pipe; CO 22H of trap unit 52The outlet is connected with the cold side inlet of the second heat exchange unit 6, the cold side outlet of the second heat exchange unit 6 is connected with the anode fuel feed inlet of the fuel cell unit 9, the anode tail gas outlet of the fuel cell unit 9 is connected with two branches, one branch is connected with an anode tail gas discharge pipe, the other branch is connected with the hot side inlet of the second heat exchange unit 6, and the hot side outlet of the second heat exchange unit 6 is connected with the inlet of the mixing device 4.
In a preferred embodiment of the present invention, a compression unit 7 is disposed on the connection pipeline between the outlet of the hot side of the second heat exchange unit 6 and the inlet of the mixing device 4.
In a preferred embodiment of the present invention, the first heat exchange unit 2 is a gas-liquid type heat exchanger, and the second heat exchange unit 6 and the third heat exchange unit 8 are gas-gas type heat exchangers.
In a preferred embodiment of the present invention, two branches of the anode tail gas outlet of the fuel cell unit 9 are respectively provided with a flow detection and control device, a pressure sensor is provided in the fuel cell unit 9, and the flow detection and control device and the pressure sensor are equally divided into two branches respectively connected to the control unit of the system.
In a preferred embodiment of the present invention, a temperature detecting device and an auxiliary heating device are disposed in the fuel cell unit 9, and the temperature detecting device and the auxiliary heating device are equally connected to the control unit of the system.
The utility model discloses a preferred embodiment, the comdenstion water export of gas-liquid separation unit 3 and first heat transfer unit 2's cold side entry linkage, be equipped with temperature-detecting device on the connecting pipeline between mixing arrangement 4's export and first heat transfer unit 2's hot side import, be equipped with flow detection and controlling means on the connecting pipeline between gas-liquid separation unit 3's comdenstion water export and first heat transfer unit 2's cold side entry, temperature-detecting device and flow detection and controlling means equally divide do not be connected with the control unit of system.
In a preferred embodiment of the present invention, the air inlet pipe and the CO2CO of the capture unit 52Outlet connection line and CO2H of trap unit 52And flow detection and control devices are arranged on the outlet connecting pipelines, and all the flow detection and control devices are respectively connected with the control unit of the system.
In a preferred embodiment of the present invention, the wall surface of the mixing device 4 is a smooth curved surface, and the mixing device 4 is provided with a turbulence member, such as a turbulence plate and a turbulence column.
The working method of the system comprises the following steps:
the methanol reforming hydrogen production unit 1 carries out methanol reforming reaction, the generated mixed gas enters the first heat exchange unit 2 through the mixing device 4 for heat exchange and condensation, and then enters the gas-liquid separation unit 3 for removing water vapor to obtain low-temperature mixed gas containing hydrogen and carbon dioxide, and the low-temperature mixed gas is subjected to CO2Separation and purification are completed in the trapping unit 5; the carbon dioxide is subjected to heat exchange and temperature rise by the third heat exchange unit 8 and then is mixed with air in the air inlet pipe, and enters a cathode fuel feeding hole of the fuel cell unit 9; the hydrogen enters an anode fuel feed inlet of the fuel cell unit 9 after being subjected to heat exchange and temperature rise by the second heat exchange unit 6, and a part of anode tail gas enters the second heat exchange unit 6 for heat exchange and temperature reduction and then enters the mixing device 4 to be mixed with the mixed gas from the methanol reforming hydrogen production unit 1.
The working principle of the utility model is as follows:
the methanol reforming hydrogen production unit 1 performs a methanol reforming reaction, and the generated mixed gas is condensed by heat exchange to remove excessive water vapor which does not participate in the reaction in the mixed gas, so as to obtain a low-temperature mixed gas mainly containing hydrogen and carbon dioxide. The low-temperature mixed gas is separated and purified by a carbon dioxide capture technology, the main component of the residual gas is hydrogen which is used as anode fuel and is introduced into the anode of the molten carbonate fuel cell after exchanging heat with the high-temperature anode tail gas, and meanwhile, the carbon dioxide which is used as cathode fuel is introduced into the cathode of the molten carbonate fuel cell after being mixed with air and exchanging heat with the high-temperature cathode tail gas.
The fuel cell unit 9 mainly includes a molten carbonate fuel cell stack, a fuel cell inlet and outlet control system, a fuel cell temperature system, an auxiliary heating system, and the like.
A molten carbonate fuel cell stack operates at 650 c, with hydrogen as the fuel at the anode and carbon dioxide and oxygen (from air) as the feed at the cathode, and electrochemical reactions occur inside the fuel cell, as shown by the following equation:
and (3) anode reaction: h2+CO3 2-→H2O+CO2+2e-
And (3) cathode reaction: 1/2O2+CO2+2e-→CO3 2-
And (3) total reaction: h2+1/2O2→H2O
The fuel cell inlet and outlet gas control system is mainly used for monitoring and adjusting the inlet gas parameters and the outlet gas parameters of the molten carbonate fuel cell in real time.
The fuel cell temperature control system and the auxiliary heating device mainly monitor and regulate the temperature of the molten carbonate fuel cell stack body in real time, and the working temperature of the fuel cell is reached or maintained through auxiliary heating when necessary.
The anode tail gas circulation and waste heat recovery system mainly comprises an anode tail gas circulation unit and a waste heat recovery unit. The anode tail gas circulation unit is used for circularly processing part of the anode tail gas, the anode tail gas mainly comprises carbon dioxide, high-temperature steam and unreacted hydrogen generated by an anode reaction, the anode tail gas is circulated to the methanol reforming hydrogen production unit and then is mixed with the methanol reforming hydrogen production tail gas, and the hydrogen and the carbon dioxide are purified through further steam condensation separation and carbon dioxide absorption/desorption separation, so that the utilization rate of the hydrogen is fully improved, and the carbon dioxide is recycled. Meanwhile, the waste heat in the tail gas is fully utilized in a heat exchange mode.
Although some terms are used in the present invention, the possibility of using other terms is not excluded. These terms are used merely for convenience in describing and explaining the nature of the present invention and are to be construed as any additional limitation which is not in accordance with the spirit of the present invention. The above description is only used as an example to further illustrate the content of the present invention, so as to facilitate understanding, but not to represent that the embodiment of the present invention is limited to this, and any technical extension or re-creation according to the present invention is protected by the present invention.
Claims (8)
1. Combined CO2The captured molten carbonate fuel cell system is characterized by comprising a methanol reforming hydrogen production unit (1), a first heat exchange unit (2), a gas-liquid separation unit (3), a mixing device (4), and CO2A capture unit (5), a second heat exchange unit (6), a third heat exchange unit (8) and a fuel cell unit (9);
the inlet of the methanol reforming hydrogen production unit (1) is connected with a methanol feeding pipe, the outlet of the methanol reforming hydrogen production unit (1) is connected with the inlet of the mixing device (4), the outlet of the mixing device (4) is connected with the inlet of the hot side of the first heat exchange unit (2), the outlet of the hot side of the first heat exchange unit (2) is connected with the gas-liquid separation unit (3), the liquid phase outlet of the gas-liquid separation unit (3) is connected with a condensed water discharging pipe, and the gas phase outlet of the gas-liquid separation unit (3) is connected with a CO discharging pipe2Connection of a capture unit (5), CO2CO of the capture unit (5)2The outlet is connected with the cold side inlet of the third heat exchange unit (8), and the cold side outlet of the third heat exchange unit (8) is connected with the air inlet pipeAfter being communicated, the tail gas outlet of the cathode of the fuel cell unit (9) is connected with the inlet of the hot side of the third heat exchange unit (8), and the outlet of the hot side of the third heat exchange unit (8) is connected with a tail gas outlet pipe of the cathode; CO 22H of the trap unit (5)2The outlet is connected with a cold side inlet of the second heat exchange unit (6), a cold side outlet of the second heat exchange unit (6) is connected with an anode fuel feed inlet of the fuel cell unit (9), an anode tail gas outlet of the fuel cell unit (9) is connected with two branches, one branch is connected with an anode tail gas discharge pipe, the other branch is connected with a hot side inlet of the second heat exchange unit (6), and a hot side outlet of the second heat exchange unit (6) is connected with an inlet of the mixing device (4).
2. The bound CO of claim 12The trapped molten carbonate fuel cell system is characterized in that a compression unit (7) is arranged on a connecting pipeline between a hot side outlet of the second heat exchange unit (6) and an inlet of the mixing device (4).
3. The bound CO of claim 12The trapped molten carbonate fuel cell system is characterized in that the first heat exchange unit (2) is a gas-liquid type heat exchanger, and the second heat exchange unit (6) and the third heat exchange unit (8) are gas-gas type heat exchangers.
4. The bound CO of claim 12The captured molten carbonate fuel cell system is characterized in that two branches connected with an anode tail gas outlet of a fuel cell unit (9) are respectively provided with a flow detection and control device, a pressure sensor is arranged in the fuel cell unit (9), and the flow detection and control device and the pressure sensor are respectively connected with a control unit of the system.
5. The bound CO of claim 12A trapped molten carbonate fuel cell system characterized in that a temperature detection device and an auxiliary heating device are provided in a fuel cell unit (9), and the temperature detection device and the auxiliary heating device are equally dividedIs connected with the control unit of the system.
6. The bound CO of claim 12The trapped molten carbonate fuel cell system is characterized in that a condensed water outlet of the gas-liquid separation unit (3) is connected with a cold side inlet of the first heat exchange unit (2), a temperature detection device is arranged on a connecting pipeline between an outlet of the mixing device (4) and a hot side inlet of the first heat exchange unit (2), a flow detection and control device is arranged on a connecting pipeline between a condensed water outlet of the gas-liquid separation unit (3) and the cold side inlet of the first heat exchange unit (2), and the temperature detection device and the flow detection and control device are respectively connected with a control unit of the system.
7. The bound CO of claim 12A trapped molten carbonate fuel cell system, characterized by an air inlet duct, CO2CO of the capture unit (5)2Outlet connection line and CO2H of the trap unit (5)2And flow detection and control devices are arranged on the outlet connecting pipelines, and all the flow detection and control devices are respectively connected with the control unit of the system.
8. The bound CO of claim 12The trapped molten carbonate fuel cell system is characterized in that the wall surface in the mixing device (4) is a smooth curved surface, and a turbulence member is provided in the mixing device (4).
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WO2022193548A1 (en) * | 2021-03-15 | 2022-09-22 | 华能国际电力股份有限公司 | Molten carbonate fuel cell system combining co2 trapping, and operation method thereof |
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WO2022193548A1 (en) * | 2021-03-15 | 2022-09-22 | 华能国际电力股份有限公司 | Molten carbonate fuel cell system combining co2 trapping, and operation method thereof |
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