CN210516883U - Natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system - Google Patents
Natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system Download PDFInfo
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- CN210516883U CN210516883U CN201920889276.8U CN201920889276U CN210516883U CN 210516883 U CN210516883 U CN 210516883U CN 201920889276 U CN201920889276 U CN 201920889276U CN 210516883 U CN210516883 U CN 210516883U
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Abstract
The utility model relates to a natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system, which comprises a natural gas self-heating reforming module, a proton exchange membrane fuel cell module, a self-heating reforming tail gas heat utilization module, a fuel cell waste heat utilization module and a connecting pipeline; the system inputs natural gas, air and working medium water, outputs electric power and multistage heat, and realizes high-efficiency cogeneration. The natural gas directly comes from the existing urban pipe network, self-heating in the system is realized by self-heating steam reforming, coupling endothermic steam reforming reaction and exothermic partial oxidation reaction, hydrogen-rich gas for the fuel cell is produced by adopting high-temperature and low-temperature steam conversion and preferential oxidation technologies, and enters the fuel cell stack system with the pressurized self-humidified air to perform electrochemical reaction, and electric power is output; meanwhile, the waste heat of the system is utilized in multiple stages, and a clean and efficient natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system is formed.
Description
Technical Field
The utility model relates to a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power generation system, the natural gas directly derives from current city pipe network, through self-heating steam reforming, the strong endothermic steam reforming reaction of coupling and exothermic partial oxidation reaction, realize the system from the heat supply, adopt high low temperature steam transform and preferential oxidation technology production hydrogen-rich gas for the fuel cell, and the air after with the pressurization humidification gets into fuel cell pile system and takes place electrochemical reaction, output power, and utilize fuel cell waste heat drive heat pump output high-quality heating power, utilize natural gas flue gas waste heat production hot water simultaneously, realize the combined heat and power generation, belong to the distributing type energy field.
Background
Currently, as a new generation energy system, a proton exchange membrane fuel cell has the advantages of energy conservation, environmental protection, small occupied area, thermoelectric ratio close to a thermoelectric demand structure, quick start, high power generation efficiency, and the function of peak clipping and valley filling for natural gas and electric power, is known as fourth generation power generation following firepower, water power and nuclear power, has been paid attention by numerous scholars at home and abroad especially in the fields of distributed power generation, household cogeneration, mobile power sources, traffic and the like, and has the most use and commercial value at present, for example, the chinese patent with the application number of 200910039095.7. However, due to various limitations such as price, safety, storage, transportation and the like, the pure hydrogen limits the large-scale application of the fuel cell to a certain extent; on the other hand, the hydrogen is produced by reforming the natural gas, the existing pipe network in cities and towns is directly utilized, and a new mode of application and popularization of the fuel cell at the present stage is developed. The natural gas reforming hydrogen production technology has multiple routes, including various modes such as steam reforming, autothermal oxidation reforming, partial oxidation, natural gas direct cracking and the like, the autothermal reforming combines the steam reforming endothermic reaction and the partial oxidation exothermic reaction, can reduce the fuel consumption to the maximum extent, and has good dynamic characteristics; in addition, in practical application, the comprehensive utilization rate of the fuel of the PEMFC power generation system is not high, mainly because the power generation efficiency of the PEMFC is influenced by various operating parameters, and a large amount of heat is generated in the power generation process, the waste heat is low in grade and difficult to utilize, but the energy is large and accounts for 40-60% of the total energy. Scientific and technological workers at home and abroad carry out various researches on heat management and waste heat utilization of fuel cells, and the main technical routes comprise waste heat heating, system preheating and waste heat refrigerating.
SUMMERY OF THE UTILITY MODEL
The utility model discloses an aim at is according to "the temperature is to the mouth, the step utilizes" principle, utilize proton exchange membrane fuel cell waste heat, shift reaction and the exothermic energy of CO preferential oxidation reaction process heat working medium water step by step, a neotype proton exchange membrane fuel cell cogeneration system based on natural gas self-heating reforming technology is proposed, it is abundant, high-efficient, excavate scientifically and utilize natural gas self-heating reforming reaction heat, proton exchange membrane fuel cell waste heat, each link heat such as burning tail gas used heat, further promote energy comprehensive utilization efficiency, increase economic profit, reduce waste heat pollution.
The utility model provides a technical scheme that above-mentioned problem adopted is: a natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system is characterized in that: the system comprises a natural gas autothermal reforming module, a proton exchange membrane fuel cell module, an autothermal reforming tail gas heat utilization module, a fuel cell waste heat utilization module and a connecting pipeline; the system inputs natural gas, air and working medium water, outputs electric power and multistage heat, and realizes high-efficiency cogeneration.
Further, the natural gas autothermal reforming module comprises a natural gas booster, an air compressor, an autothermal reformer, a combustor, a high-temperature shift reactor, a low-temperature shift reactor, a CO oxidation reactor, a #1- #4 heat exchanger, a #5 integrated heat exchanger, a natural gas pipeline, an air pipeline, a working medium water pipeline and a synthesis gas pipeline; the natural gas outlet of the natural gas booster is divided into two paths, one path is connected with the inlet of the burner, and the other path is connected with the natural gas inlet of the #5 integrated heat exchanger; the air outlet of the air compressor is divided into four paths, wherein one path of air outlet is connected with the air inlet of the combustor, one path of air outlet is connected with the air inlet of the CO oxidation reactor, and the other path of air outlet is connected with the air inlet of the #5 integrated heat exchanger; a natural gas outlet, an air outlet and a steam outlet of the #5 integrated heat exchanger are combined and then connected with an inlet of the self-heating reformer, a synthesis gas outlet of the self-heating reformer is connected with a synthesis gas inlet of the #5 integrated heat exchanger, an inlet of the high-temperature shift reactor is connected with a synthesis gas outlet of the #4 heat exchanger, an outlet of the high-temperature shift reactor is connected with a synthesis gas inlet of the #3 heat exchanger, an inlet of the low-temperature shift reactor is connected with a synthesis gas outlet of the #3 heat exchanger, an outlet of the low-temperature shift reactor is connected with a synthesis gas inlet of the #2 heat exchanger, a synthesis gas outlet of the #2 heat exchanger is connected with a synthesis gas inlet of the CO oxidation reactor, and an outlet of the CO oxidation reactor is connected with a synthesis gas inlet of the #1 heat exchanger; the working medium water pipeline is connected with the working medium water inlet of the #1 heat exchanger, the working medium water outlet of the #1 heat exchanger is connected with the working medium water inlet of the #2 heat exchanger, the working medium water outlet of the #2 heat exchanger is connected with the working medium water inlet of the #3 heat exchanger, the working medium water outlet of the #3 heat exchanger is connected with the working medium water inlet of the #4 heat exchanger, the working medium water outlet of the #4 heat exchanger is connected with the working medium water inlet of the #5 integrated heat exchanger, and the working medium water outlet of the #5 integrated heat exchanger is connected with the mixed gas inlet of the self-heating reformer.
Further, the proton exchange membrane fuel cell module comprises a proton exchange membrane fuel cell body, the air compressor, an air cooler, a humidifier, an inverter, an air pipeline and a cooling water pipeline; an anode hydrogen inlet of the proton exchange membrane fuel cell body is connected with a synthesis gas outlet of the #1 heat exchanger, a cathode air inlet of the proton exchange membrane fuel cell body is connected with an air outlet of the humidifier, one path of air outlet of the air compressor is connected with an air inlet of the air cooler, an air outlet of the air cooler is connected with an air inlet of the humidifier, and electric power generated by the proton exchange membrane fuel cell body is output through the inverter.
Further, the self-heating reforming tail gas heat utilization module comprises a #6 hot water heat exchanger, a temperature rise type heat pump unit, the air cooler, a tail gas pipeline, a cooling water pipeline, a hot water pipeline and a heat distribution pipeline; tail gas generated after the natural gas and the air are combusted in the combustor is used for heating cooling water in the #6 hot water heat exchanger to supply heat; the cooling water pipeline is divided into two paths, one path is connected with a cooling water inlet of the air cooler, the other path is connected with a cooling water inlet of the temperature-rise heat pump unit, a cooling water outlet of the temperature-rise heat pump unit is connected with a cooling water inlet of the #6 hot water heat exchanger, and a cooling water outlet of the air cooler is connected with a cooling water inlet of the #6 hot water heat exchanger; the cooling water outlet of the #6 hot water heat exchanger is divided into two paths, one path is connected with the hot water pipeline to directly provide hot water for a user, and the other path is connected with the hot water inlet of the temperature-rising heat pump unit; the temperature-rising heat pump unit provides heat products such as steam and the like for users through the heat pipeline.
Further, the fuel cell waste heat utilization module comprises the proton exchange membrane fuel cell body, the temperature rise type heat pump unit, the humidifier and a circulating water pump; the cooling water outlet of the proton exchange membrane fuel cell body is connected with the driving heat source inlet of the temperature rise type heat pump unit, the driving heat source outlet of the temperature rise type heat pump unit is connected with the inlet of the circulating water pump, the outlet of the circulating water pump is connected with the cooling water inlet of the proton exchange membrane fuel cell body, the cathode water vapor outlet of the proton exchange membrane fuel cell body is connected with the water vapor inlet of the humidifier, and the anode hydrogen outlet of the proton exchange membrane fuel cell body is connected with the natural gas inlet of the combustor.
Hydrogen of the proton exchange membrane fuel cell is derived from natural gas autothermal reforming, based on the existing urban natural gas pipe network, steam is heated and preheated to the required temperature step by step through working medium water, mixed gas is prepared through coupling steam reforming reaction and partial oxidation reaction, carbon monoxide in the mixed gas is eliminated through high-low temperature shift reaction and preferential oxidation reaction, and hydrogen-rich gas for the fuel cell is produced; oxygen of the PEMFC power generation system is directly derived from air, is pressurized and heated by the air compressor and then enters the fuel cell to generate electrochemical reaction with hydrogen, and electric power is output.
After desulfurization and purification and other processes, the natural gas enters the supercharger, and is used as a fuel source of the combustor to be mixed with the tail gas and air of the proton exchange membrane fuel cell body to burn so as to provide heat for the autothermal reformer, and the reaction of the formula (1):
CH4+2O2→CO2+2H2O -802.7kJ/mol (1)
the burned flue gas passes through the #5 integrated heat exchanger and the #6 hot water heat exchanger to preheat natural gas, working medium water and air which enter the self-heating reformer, and then the cooling water from the air cooler and the temperature-rising heat pump unit is heated;
after being heated and heated by the #5 integrated heat exchanger, natural gas is mixed with heated air and water and enters the autothermal reformer to mainly carry out reactions of the formulas (2) and (3) to generate synthesis gas, wherein the synthesis gas comprises hydrogen, carbon monoxide, methane, carbon dioxide, steam and nitrogen:
CH4+0.5O2→CO+2H2-35.7kJ/mol (2)
CH4+H2O→CO+3H2+206.2kJ/mol (3)
the superheated steam heated to a certain temperature by the external working medium water through the heat exchangers #1- #4 and the integrated heat exchanger #5 enters the self-heating reformer; according to the principle of 'temperature to port and cascade utilization', the self reaction energy of the system is utilized to heat the working medium water step by step to generate high-temperature steam, compared with the traditional method of directly utilizing the combustor to generate the high-temperature steam, the combustion amount of natural gas can be saved, and the comprehensive efficiency of system energy is equivalently improved;
the synthesis gas enters the high-temperature shift reactor after being cooled to a certain temperature through the #5 integrated heat exchanger and the #4 heat exchanger in two stages, then enters the low-temperature shift reactor after being cooled to a certain temperature through the #3 heat exchanger, and generates (4) type steam shift reaction, so that the CO content is reduced, and the synthesis gas comprises hydrogen, carbon monoxide, methane, carbon dioxide, water vapor and nitrogen:
CO+H2O→H2+CO2-41.2kJ/mol (4)
the CO content after the shift reaction still can not meet the requirements of the proton exchange membrane fuel cell body, the CO enters the CO oxidation reactor after being cooled to a certain temperature by the #3 heat exchanger, the (5) type reaction is carried out, the CO is further removed, the CO concentration is controlled to be below 10ppm, and hydrogen-rich gas is produced and comprises hydrogen, carbon monoxide, methane, carbon dioxide, water vapor and nitrogen:
CO+H2+O2→CO2+H2O -524.8kJ/mol (5)
and hydrogen-rich gas enters the proton exchange membrane fuel cell body and carries out electrochemical reaction, wherein the formula is as follows (6):
2H2→4H++4e-(6)
step 8, pressurizing the air after passing through the filter by the air compressor, cooling the air, performing heat and humidity exchange on the cooled air and the tail gas of the cathode reaction of the proton exchange membrane fuel cell body through the humidifier, and allowing the wet air to enter the cathode side of the proton exchange membrane fuel cell body to perform an electrochemical reaction, wherein the formula is (7):
O2+4H++4e-→2H2O (7)
in order to ensure the normal operation of the fuel cell system and maintain the optimal working temperature, the heat generated by the electrochemical reaction needs to be released in time, the residual heat source is used as a driving heat source of the temperature-rising heat pump unit, part of hot water from the #6 hot water heat exchanger is heated to thermal products such as hot steam and the like for high-quality heat supply or steam supply, and after driving and heat release, the hot water is continuously circulated to the proton exchange membrane fuel cell body, so that the high-quality heat can be provided compared with the traditional method for directly cooling and discharging or producing hot water, and the comprehensive utilization efficiency of energy resources is further improved.
Preferably, the humidifier is a porous carbon plate humidifier.
Preferably, the temperature-rise heat pump unit is a lithium bromide hot water driven temperature-rise heat pump unit.
A method for a distributed cogeneration system of natural gas autothermal reforming proton exchange membrane fuel cells, which uses the distributed cogeneration system of natural gas autothermal reforming proton exchange membrane fuel cells, comprises the following steps:
(1) when the autothermal reforming system works, after the natural gas is pressurized by the natural gas booster, one path of the natural gas is used as a combustor fuel, and the other path of the natural gas is heated by the heat exchanger and then enters the autothermal reformer. The air is pressurized by an air compressor and then divided into three paths to enter an autothermal reforming system, one path of the air enters a combustor to supply oxygen for combustion reaction, the other path of the air enters a CO oxidation reactor to supply oxygen, and the other path of the air enters the autothermal reformer after being heated by a heat exchanger to react. The synthesis gas after the reaction of the self-heating reformer is cooled by the heat exchanger twice and then enters the high-temperature shift reactor for reaction, the synthesis gas after the reaction of the high-temperature shift reactor is cooled by the heat exchanger and then enters the low-temperature shift reactor for reaction, the synthesis gas after the reaction of the low-temperature shift reactor is cooled by the heat exchanger and then enters the CO oxidation reactor for reaction, and the synthesis gas after the reaction of the CO oxidation reactor is cooled by the heat exchanger and then enters the proton exchange membrane fuel cell for providing hydrogen for the reaction of the fuel cell.
(2) When the proton exchange membrane fuel cell works, air is compressed by an air compressor, cooled by an air cooler, and humidified by a humidifier to supply oxygen for the reaction of the fuel cell; the autothermal reforming system supplies hydrogen for the reaction of the fuel cell through autothermal reforming, and the hydrogen and the oxygen generate electricity after the reaction in the fuel cell, and simultaneously provides a driving heat source for the waste heat utilization system.
(3) The heat utilization during the work of the autothermal reforming system comprises two parts, wherein one part is heat generated in the reaction process, and after being collected by a series of heat exchangers, working medium water generates steam and enters the autothermal reformer; the other part is heat taken away by waste gas generated by combustion reaction, and the waste gas is discharged after being cooled by the heat exchanger twice. The cooling water is heated by the air cooler and the heat exchanger to provide hot water.
(4) The waste heat utilization when the fuel cell works, and the heat generated when the proton exchange membrane fuel cell reacts is taken away by waste gas and condensed water. The heat carried away by the exhaust gas is divided into two parts, wherein the exhaust gas generated by the anode is returned to the autothermal reforming system to provide heat for the autothermal reformer; the waste gas generated by the cathode returns to the fuel cell after being humidified and heat exchanged by the humidifier to provide heat for the reaction of the fuel cell; the condensed water generated by the reaction is cooled by the temperature-rising heat pump and then returns to the fuel cell, and the circulation work is carried out, so that the purpose of waste heat utilization is achieved.
The utility model discloses carry out multistage utilization to the waste heat of system, utilize self-heating reforming reaction heat to be geared to the needs according to "the temperature, the step utilizes" principle to heat working medium water step by step and produces steam and participate in the reforming reaction, utilizes proton exchange membrane fuel cell waste heat drive temperature rise type heat pump set output high-quality heating power, utilizes the tail gas waste heat after the natural gas burning to preheat fuel and heating production hot water.
Compared with the prior art, the utility model, have following advantage and effect:
1. the utility model discloses a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power system inputs natural gas, air and working medium water, and many qualities electric power and heating power products such as exportable electric power, hot water and hot steam are a new distributed energy system, can realize the cogeneration.
2. The utility model discloses a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power generation system utilizes current cities and towns natural gas pipe network to self-heating reforming technology is the basis, combines endothermic steam reforming reaction and exothermic partial oxidation reaction, produces hydrogen-rich gas, solves the bottleneck problem that restriction proton exchange membrane fuel cell scale was used such as pure hydrogen price height, transportation difficulty.
3. The utility model discloses a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power generation system utilizes "temperature is to mouthful, and the step utilizes" principle, utilizes the reaction heat among the self-heating reforming process, heats working medium water step by step, produces steam and carries out the steam reforming reaction, has reduced the natural gas combustion volume, is equivalent to promotion energy comprehensive efficiency.
4. The utility model discloses a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power generation system utilizes the temperature rise type absorption heat pump degree of depth to excavate proton exchange membrane fuel cell's waste heat, as the drive heat source, provides the steam energy of high-quality for the user.
5. The utility model discloses a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power generation system, make full use of burning tail gas used heat carries out the multilevel utilization as natural gas, air, working medium water preheat and life hydrothermal energy source to the used heat of system, strives for to exhaust the used heat and exhausts, and energy utilization efficiency obtains promoting when the thermal pollution reduces.
6. The utility model discloses a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power generation system utilizes the water that fuel cell reaction produced to admit air the water source of humidification as the air, is a new proton exchange membrane fuel cell self-humidifying mode.
Drawings
Fig. 1 is a flow diagram of a natural gas autothermal reforming module in accordance with an embodiment of the present invention.
Fig. 2 is a flow chart of a pem fuel cell module according to an embodiment of the present invention.
FIG. 3 is a flow chart of an autothermal reforming tail gas heat utilization module according to an embodiment of the present invention.
Fig. 4 is a flow chart of a fuel cell waste heat utilization module according to an embodiment of the present invention.
Fig. 5 is a system flow diagram of an embodiment of the invention.
In the figure: the system comprises a supercharger 1, an autothermal reformer 2, a combustor 3, a high-temperature shift reactor 4, a low-temperature shift reactor 5, a CO oxidation reactor 6, a #5 integrated heat exchanger 7, a #4 heat exchanger 8, a #3 heat exchanger 9, a #2 heat exchanger 10, a #1 heat exchanger 11, a #6 hot water heat exchanger 12, a temperature rise type heat pump unit 13, a circulating water pump 14, a proton exchange membrane fuel cell body 15, an air compressor 16, an air cooler 17, a humidifier 18, an inverter 19 and a working medium water pipeline 20.
Detailed Description
The present invention will be described in further detail by way of examples with reference to the accompanying drawings, which are illustrative of the present invention and are not intended to limit the present invention.
As shown in fig. 5, the distributed cogeneration system for natural gas autothermal reforming pem fuel cell according to the present embodiment includes a supercharger 1, an autothermal reformer 2, a combustor 3, a high-temperature shift reactor 4, a low-temperature shift reactor 5, a CO oxidation reactor 6, a #5 integrated heat exchanger 7, a #4 heat exchanger 8, a #3 heat exchanger 9, a #2 heat exchanger 10, a #1 heat exchanger 11, a #6 hot water heat exchanger 12, a temperature-rising heat pump unit 13, a circulating water pump 14, a pem fuel cell body 15, an air compressor 16, an air cooler 17, a humidifier 18, and an inverter 19.
The natural gas export of natural gas booster compressor 1 in this embodiment divides into two the tunnel, all the way with the access connection of combustor 3, another way with the natural gas access connection of #5 integrated heat exchanger 7, the air outlet of air compressor machine 16 divides into four the tunnel, wherein export and the air intlet of combustor 3 are connected all the way, export and the air intlet of CO oxidation reactor 6 are connected all the way, all the way with the air intlet of #5 integrated heat exchanger 7 is connected, in addition all the way with the air intlet of air cooler 17 and be connected. The natural gas outlet, the air outlet and the steam outlet of the integrated heat exchanger 7 are combined and then connected with the inlet of the self-heating reformer 2, the synthesis gas outlet of the self-heating reformer 2 is connected with the synthesis gas inlet of the #5 integrated heat exchanger 7, the inlet of the high-temperature shift reactor 4 is connected with the synthesis gas outlet of the #4 heat exchanger 8, the outlet of the high-temperature shift reactor 4 is connected with the synthesis gas inlet of the #3 heat exchanger 9, the inlet of the low-temperature shift reactor 5 is connected with the synthesis gas outlet of the #3 heat exchanger 9, the outlet of the low-temperature shift reactor 5 is connected with the synthesis gas inlet of the #2 heat exchanger 10, the synthesis gas outlet of the #2 heat exchanger 10 is connected with the synthesis gas inlet of the CO oxidation reactor 6, and the outlet of the CO oxidation reactor 6 is connected with the synthesis gas inlet of. The working medium water pipeline 20 is connected with a working medium water inlet of the #1 heat exchanger 11, a working medium water outlet of the #1 heat exchanger 11 is connected with a working medium water inlet of the #2 heat exchanger 10, a working medium water outlet of the #2 heat exchanger 10 is connected with a working medium water inlet of the #3 heat exchanger 9, a working medium water outlet of the #3 heat exchanger 9 is connected with a working medium water inlet of the #4 heat exchanger 8, a working medium water outlet of the #4 heat exchanger 8 is connected with a working medium water inlet of the #5 integrated heat exchanger 7, and an outlet of the #5 integrated heat exchanger 7 is connected with a mixer inlet of the self-heating reformer 2. The hydrogen inlet of the proton exchange membrane fuel cell body 15 is connected with the synthesis gas outlet of the #1 heat exchanger 11, the cathode air inlet of the proton exchange membrane fuel cell body 15 is connected with the outlet air of the humidifier 18, and the air outlet of the air cooler 17 is connected with the air inlet of the humidifier 18. The inverter 19 is connected to the proton exchange membrane fuel cell body 15. The mixed gas inlet of the #6 hot water heat exchanger 12 is connected with the synthesis gas outlet of the #5 integrated heat exchanger 7. The cooling water pipeline is divided into two paths, one path is connected with a cooling water inlet of the air cooler 17, the other path is connected with a cooling water inlet of the temperature-rise heat pump unit 13, a cooling water outlet of the temperature-rise heat pump unit 13 is connected with a cooling water inlet of the #6 hot water heat exchanger 12, and a cooling water outlet of the air cooler 17 is connected with a cooling water inlet of the #6 hot water heat exchanger 12. The cooling water outlet of the #6 hot water heat exchanger 12 is divided into two paths, one path is connected to a hot water pipeline, the other path is connected to a hot water inlet of the temperature rise heat pump unit 13, and a hot water outlet of the temperature rise heat pump unit 13 is connected to a heat distribution pipeline. And the tail gas outlet of the #6 hot water heat exchanger 12 is connected with a tail gas pipeline. The cooling water outlet of the proton exchange membrane fuel cell body 15 is connected with the driving heat source inlet of the temperature-rising heat pump 13, the driving heat source outlet of the temperature-rising heat pump 13 is connected with the inlet of the circulating water pump 14, and the outlet of the circulating water pump 14 is connected with the driving heat source inlet of the proton exchange membrane fuel cell body 15. The cathode water vapor outlet of the pem fuel cell body 15 is connected to the water vapor inlet of the humidifier 18. The anode cooling water outlet of the proton exchange membrane fuel cell body 15 is connected with the synthesis gas inlet of the combustor 3.
The method of the distributed cogeneration system of the natural gas autothermal reforming proton exchange membrane fuel cell in the embodiment comprises the following specific processes:
(1) when the distributed cogeneration system of the natural gas autothermal reforming pem fuel cell starts to operate, the natural gas autothermal reforming system starts to operate, and as shown in fig. 1, natural gas is pressurized by a supercharger 1, heated by a #5 integrated heat exchanger 7, and then enters an autothermal reformer 2. Air is pressurized by an air compressor 16 and then is divided into three paths to enter an autothermal reforming system, one path of air enters a combustor 3 to supply oxygen for combustion reaction, the other path of air enters a CO reactor 6 to supply oxygen, and the other path of air enters an autothermal reformer 2 after being heated by a #5 integrated heat exchanger 7 to react. The synthesis gas after the reaction of the self-heating reformer 2 enters the high-temperature shift reactor 4 for reaction after being cooled by the #5 integrated heat exchanger 7 and the #4 heat exchanger 8 twice, the synthesis gas after the reaction of the high-temperature shift reactor 4 enters the low-temperature shift reactor 5 for reaction after being cooled by the #3 heat exchanger 9, the synthesis gas after the reaction of the low-temperature shift reactor 5 enters the CO oxidation reactor 6 for reaction after being cooled by the #2 heat exchanger 10, the synthesis gas after the reaction of the CO oxidation reactor 6 enters the fuel cell 15 through a synthesizer pipeline after being cooled by the #1 heat exchanger 11, and hydrogen is provided for the reaction of the fuel cell.
(2) When the natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system starts to operate, the proton exchange membrane fuel cell starts to work, as shown in fig. 2, air is compressed by an air compressor 16, cooled by an air cooler 17, and humidified by a humidifier 18 to supply oxygen for the reaction of the fuel cell 15; the autothermal reforming system supplies hydrogen for the fuel cell reaction by autothermal reforming, and the hydrogen and oxygen react in the fuel cell to provide electricity.
(3) When the natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system starts to operate, the heat utilization system of the autothermal reforming system starts to work, as shown in fig. 1 and fig. 3, a part of the heat is generated in the reaction process, and working medium water enters the autothermal reformer 2 after collecting the heat of the synthesis gas in the whole autothermal reforming reaction through the #1 heat exchanger 11, the #2 heat exchanger 10, the #3 heat exchanger 9, the #4 heat exchanger 8 and the #5 integrated heat exchanger 7 to provide heat for the autothermal reforming reaction. The other part is the heat carried away by the waste gas generated by the reaction, and the waste gas is discharged after being cooled by the #5 integrated heat exchanger 7 and the #6 hot water heat exchanger 12. The cooling water passes through the air cooler 17 and then passes through the #6 heat exchanger 12, absorbs heat emitted from the exhaust gas, and is heated up, thereby providing hot water.
(4) When the natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system starts to operate, the waste heat utilization system of the fuel cell starts to operate, and as shown in fig. 4, heat generated during the reaction of the fuel cell 15 is taken away by the exhaust gas and the condensed water. The heat carried away by the exhaust gas is divided into two portions, wherein the exhaust gas produced by the anode is returned to the autothermal reformer system to provide heat to the autothermal reformer 2; the waste gas generated by the cathode is humidified by the humidifier 18 and then returns to the fuel cell 15 to provide heat for the fuel cell reaction; the condensed water generated by the reaction is cooled by the temperature-rising heat pump 13 and then returns to the fuel cell to provide heat for the fuel cell reaction.
The utility model discloses a natural gas self-heating reforming proton exchange membrane fuel cell distributing type combined heat and power generation system's energy utilization efficiency is high, and economic benefits is good, has still promoted the income of system when eliminating thermal pollution.
Although the present invention has been described with reference to the above embodiments, it should not be construed as being limited to the scope of the present invention, and any modifications made by those skilled in the art without departing from the spirit and scope of the present invention should be construed as being included in the following claims.
Claims (7)
1. A natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system is characterized in that: the system comprises a natural gas autothermal reforming module, a proton exchange membrane fuel cell module, an autothermal reforming tail gas heat utilization module, a fuel cell waste heat utilization module and a connecting pipeline; the system inputs natural gas, air and working medium water, outputs electric power and multistage heat, and realizes high-efficiency cogeneration.
2. The natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system of claim 1, the natural gas autothermal reforming module comprising a natural gas booster, an air compressor, an autothermal reformer, a burner, a high temperature shift reactor, a low temperature shift reactor, a CO oxidation reactor, #1- #4 heat exchanger, #5 integrated heat exchanger, a natural gas pipeline, an air pipeline, a working fluid water pipeline, a syngas pipeline, characterized in that: the natural gas outlet of the natural gas booster is divided into two paths, one path is connected with the inlet of the burner, and the other path is connected with the natural gas inlet of the #5 integrated heat exchanger; the air outlet of the air compressor is divided into four paths, wherein one path of air outlet is connected with the air inlet of the combustor, one path of air outlet is connected with the air inlet of the CO oxidation reactor, and the other path of air outlet is connected with the air inlet of the #5 integrated heat exchanger; a natural gas outlet, an air outlet and a steam outlet of the #5 integrated heat exchanger are combined and then connected with an inlet of the self-heating reformer, a synthesis gas outlet of the self-heating reformer is connected with a synthesis gas inlet of the #5 integrated heat exchanger, an inlet of the high-temperature shift reactor is connected with a synthesis gas outlet of the #4 heat exchanger, an outlet of the high-temperature shift reactor is connected with a synthesis gas inlet of the #3 heat exchanger, an inlet of the low-temperature shift reactor is connected with a synthesis gas outlet of the #3 heat exchanger, an outlet of the low-temperature shift reactor is connected with a synthesis gas inlet of the #2 heat exchanger, a synthesis gas outlet of the #2 heat exchanger is connected with a synthesis gas inlet of the CO oxidation reactor, and an outlet of the CO oxidation reactor is connected with a synthesis gas inlet of the #1 heat exchanger; the working medium water pipeline is connected with the working medium water inlet of the #1 heat exchanger, the working medium water outlet of the #1 heat exchanger is connected with the working medium water inlet of the #2 heat exchanger, the working medium water outlet of the #2 heat exchanger is connected with the working medium water inlet of the #3 heat exchanger, the working medium water outlet of the #3 heat exchanger is connected with the working medium water inlet of the #4 heat exchanger, the working medium water outlet of the #4 heat exchanger is connected with the working medium water inlet of the #5 integrated heat exchanger, and the working medium water outlet of the #5 integrated heat exchanger is connected with the mixed gas inlet of the self-heating reformer.
3. The natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system of claim 2, the proton exchange membrane fuel cell module comprising a proton exchange membrane fuel cell body, the air compressor, an air cooler, a humidifier, an inverter, an air pipe, a cooling water pipe, wherein: an anode hydrogen inlet of the proton exchange membrane fuel cell body is connected with a synthesis gas outlet of the #1 heat exchanger, a cathode air inlet of the proton exchange membrane fuel cell body is connected with an air outlet of the humidifier, one path of air outlet of the air compressor is connected with an air inlet of the air cooler, an air outlet of the air cooler is connected with an air inlet of the humidifier, and electric power generated by the proton exchange membrane fuel cell body is output through the inverter.
4. The natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system of claim 3, the autothermal reforming tail gas heat utilization module comprising a #6 hot water heat exchanger, a temperature-rising heat pump unit, the air cooler, a tail gas pipeline, a cooling water pipeline, a hot water pipeline, a heat pipeline, characterized in that: tail gas generated after the natural gas and the air are combusted in the combustor is used for heating cooling water in the #6 hot water heat exchanger to supply heat; the cooling water pipeline is divided into two paths, one path is connected with a cooling water inlet of the air cooler, the other path is connected with a cooling water inlet of the temperature-rise heat pump unit, a cooling water outlet of the temperature-rise heat pump unit is connected with a cooling water inlet of the #6 hot water heat exchanger, and a cooling water outlet of the air cooler is connected with a cooling water inlet of the #6 hot water heat exchanger; the cooling water outlet of the #6 hot water heat exchanger is divided into two paths, one path is connected with the hot water pipeline to directly provide hot water for a user, and the other path is connected with the hot water inlet of the temperature-rising heat pump unit; the temperature-rising heat pump unit provides a thermal product for a user through the thermal pipeline.
5. The natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system of claim 4, the fuel cell waste heat utilization module comprising the proton exchange membrane fuel cell body, the temperature-rising heat pump unit, the humidifier, and a circulating water pump, wherein: the cooling water outlet of the proton exchange membrane fuel cell body is connected with the driving heat source inlet of the temperature rise type heat pump unit, the driving heat source outlet of the temperature rise type heat pump unit is connected with the inlet of the circulating water pump, the outlet of the circulating water pump is connected with the cooling water inlet of the proton exchange membrane fuel cell body, the cathode water vapor outlet of the proton exchange membrane fuel cell body is connected with the water vapor inlet of the humidifier, and the anode hydrogen outlet of the proton exchange membrane fuel cell body is connected with the natural gas inlet of the combustor.
6. The natural gas autothermal reforming pem fuel cell distributed cogeneration system of claim 3, said pem fuel cell module further characterized by: the humidifier is a porous carbon plate humidifier.
7. The natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system of claim 5, said fuel cell waste heat utilization module, further characterized by: the temperature-rising heat pump unit is a lithium bromide hot water driven temperature-rising heat pump unit.
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110544785A (en) * | 2019-06-13 | 2019-12-06 | 华电电力科学研究院有限公司 | natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system and method |
| CN112713285A (en) * | 2020-12-29 | 2021-04-27 | 国科微城市智能科技(南京)有限责任公司 | Hydrogen fuel cell temperature regulation and control device |
| CN114142583A (en) * | 2021-10-29 | 2022-03-04 | 西安交通大学 | Hybrid power supply system |
| CN118221073A (en) * | 2024-05-20 | 2024-06-21 | 南京航空航天大学 | Comprehensive waste heat utilization system for coupling PEMFC power generation and natural gas on-site reforming hydrogen production |
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- 2019-06-13 CN CN201920889276.8U patent/CN210516883U/en active Active
Cited By (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110544785A (en) * | 2019-06-13 | 2019-12-06 | 华电电力科学研究院有限公司 | natural gas self-heating reforming proton exchange membrane fuel cell distributed cogeneration system and method |
| CN110544785B (en) * | 2019-06-13 | 2024-06-04 | 华电电力科学研究院有限公司 | Natural gas autothermal reforming proton exchange membrane fuel cell distributed cogeneration system and method |
| CN112713285A (en) * | 2020-12-29 | 2021-04-27 | 国科微城市智能科技(南京)有限责任公司 | Hydrogen fuel cell temperature regulation and control device |
| CN112713285B (en) * | 2020-12-29 | 2022-02-22 | 国科微城市智能科技(南京)有限责任公司 | Hydrogen fuel cell temperature regulation and control device |
| CN114142583A (en) * | 2021-10-29 | 2022-03-04 | 西安交通大学 | Hybrid power supply system |
| CN114142583B (en) * | 2021-10-29 | 2024-07-16 | 西安交通大学 | Hybrid power supply system |
| CN118221073A (en) * | 2024-05-20 | 2024-06-21 | 南京航空航天大学 | Comprehensive waste heat utilization system for coupling PEMFC power generation and natural gas on-site reforming hydrogen production |
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