CN217789312U - Hydrogen production fuel cell measurement experimental device based on wind power - Google Patents

Hydrogen production fuel cell measurement experimental device based on wind power Download PDF

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Publication number
CN217789312U
CN217789312U CN202220030981.4U CN202220030981U CN217789312U CN 217789312 U CN217789312 U CN 217789312U CN 202220030981 U CN202220030981 U CN 202220030981U CN 217789312 U CN217789312 U CN 217789312U
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fuel cell
wind power
power generation
hydrogen production
wind
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陆紫生
崔航宁
王少泽
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Shanghai Jiaotong University
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Shanghai Jiaotong University
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    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/30Hydrogen technology
    • Y02E60/50Fuel cells

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Abstract

A hydrogen production fuel cell measurement experimental device based on wind power comprises: the hydrogen fuel cell unit, and the wind power generation mechanism and the photovoltaic power generation mechanism which are respectively connected with the hydrogen fuel cell unit, wherein the loads of the wind power generation mechanism and the electrolytic hydrogen production device are provided with sensing detector combinations connected with a data acquisition instrument; the sensing detector group comprises: the system comprises a pressure sensor, a temperature sensor and a flowmeter which are arranged on the wind power generation mechanism and are respectively connected with a data acquisition instrument, and a power meter which is respectively connected with a load and the data acquisition instrument. The device can realize the comprehensive performance test of wind-solar power generation, hydrogen production, hydrogen storage and fuel cell power generation under multiple working conditions.

Description

Hydrogen production fuel cell measurement experimental device based on wind power
Technical Field
The utility model relates to a technique in the field of gas measurement, in particular to a comprehensive measurement experimental device for wind-solar power generation, hydrogen production, hydrogen storage by adsorption and fuel cells.
Background
The existing hydrogen energy testing technology can not realize various functions of wind-solar power generation, hydrogen production, hydrogen storage and fuel cell power generation and can not realize comprehensive performance testing of wind-solar power generation, hydrogen production, hydrogen storage and fuel cell power generation under multiple working conditions by using wind energy and solar energy.
SUMMERY OF THE UTILITY MODEL
The utility model discloses to the above-mentioned not enough that prior art exists, provide a hydrogen manufacturing fuel cell measurement experimental apparatus based on wind-powered electricity generation, can realize the complementary electricity generation of photoelectricity, the electricity of production can electrolytic water hydrogen manufacturing, the hydrogen of production can be adsorbed hydrogen storage, can desorb hydrogen when using, the hydrogen of desorption is used for fuel cell electricity generation.
The utility model discloses a realize through following technical scheme:
the utility model discloses a: hydrogen fuel cell unit and wind power generation mechanism and photovoltaic power generation mechanism that link to each other respectively, wherein: the loads of the wind power generation mechanism and the electrolytic hydrogen production device are provided with a sensing detector combination connected with a data acquisition instrument.
The sensing detector group comprises: the system comprises a pressure sensor, a temperature sensor and a flowmeter which are arranged on the wind power generation mechanism and are respectively connected with a data acquisition instrument, and a power meter which is respectively connected with a load and the data acquisition instrument.
The wind power generation mechanism comprises: tuber pipe, set up in axial fan and aerogenerator at its both ends, wherein: the output end of the wind driven generator is connected with the electrolytic hydrogen production device.
The photovoltaic power generation mechanism comprises: photovoltaic board and xenon lamp that relative setting, wherein: the output end of the photovoltaic panel is connected with the electrolytic hydrogen production device.
The hydrogen fuel cell unit includes: the electrolytic water hydrogen production device, the adsorption hydrogen storage device and the fuel cell are connected in sequence, wherein: the output end of the fuel cell is provided with a load.
Drawings
FIG. 1 is a schematic view of the structure of the utility model;
FIG. 2 is a schematic view of an adsorbent hydrogen storage vessel;
in the figure: the device comprises a frequency converter 1, an axial flow fan 2, a pressure sensor 3, a temperature sensor 4, a flowmeter 5, an air distributor 6, an air pipe 7, blades 8, a generator 9, a first height adjusting support 10, a second height adjusting support 11, a photovoltaic panel 12, an irradiator 13, an electrolyzed water hydrogen generator 14, an adsorption hydrogen storage device 15, a fuel cell 16, a bulb 17, a power meter 18, a data acquisition device 19, a xenon lamp 20, a heat exchange fluid inlet quick connector 21, an outer wall 22, a hydrogen inlet quick connector 23, an inner wall 24, an adsorbent 25, a heat exchange fluid outlet quick connector 26 and a hydrogen outlet quick connector 27.
Detailed Description
As shown in fig. 1, the experimental apparatus for measuring hydrogen production fuel cell based on wind power according to the present embodiment includes: hydrogen fuel cell unit and wind power generation mechanism and photovoltaic power generation mechanism that links to each other respectively wherein: the loads of the wind power generation mechanism and the electrolytic hydrogen production device are provided with a sensing detector combination connected with a data acquisition instrument.
The sensing detector group comprises: the system comprises a pressure sensor 3, a temperature sensor 4, a flowmeter 5 and a power meter 18, wherein the pressure sensor 3, the temperature sensor 4 and the flowmeter 5 are arranged on the wind power generation mechanism and are respectively connected with a data acquisition instrument 19, and the power meter 18 is respectively connected with a load and the data acquisition instrument 19.
The wind power generation mechanism comprises: tuber pipe 7, set up in axial fan 2 and the generator 9 that has blade 8 at its both ends, wherein: the generator 9 is movably arranged and the output end thereof is connected with the electrolytic hydrogen production device.
The generator 9 is arranged on the first height-adjusting support 10, and the relative position of the generator and the axial flow fan 2 is adjusted through the first height-adjusting support 10.
And an air distributor 6 is arranged on one side of the air pipe 7 close to the axial flow fan 2 to output a more uniform wind field.
The axial flow fan 2 is connected with the frequency converter 1, and the wind speed is adjusted by adjusting the output frequency of the frequency converter.
The photovoltaic power generation mechanism comprises: an oppositely disposed photovoltaic panel 12 and a xenon lamp 20, wherein: the output end of the photovoltaic panel 12 is connected with an electrolytic hydrogen production device, and the xenon lamp 20 is movably arranged.
The xenon lamp 20 is arranged on the second height-adjusting support 11 to adjust the position between the xenon lamp and the photovoltaic panel 12, and the irradiation intensity can be controlled by adjusting the second height-adjusting support 11 to change the height of the xenon lamp.
The hydrogen fuel cell unit includes: the electrolytic water hydrogen production device 14, the adsorption hydrogen storage device 15 and the fuel cell 16 are connected in sequence, wherein: the output of the fuel cell 16 is provided with a load.
The load is a light bulb 17.
The working process of the device is as follows: step 1), aligning an air pipe 7 with blades; step 2) aligning the xenon lamp 20 with the photovoltaic panel 12; step 3), connecting the wires of the photovoltaic panel 12 and the wires of the wind driven generator 9 with the positive electrode and the negative electrode of the electrolyzed water hydrogen production device 14; step 4), adding deionized water into the hydrogen production device 14; step 5), connecting a hydrogen pipe of the hydrogen producer 14 with an adsorption hydrogen storage device 15; step 6), connecting a hydrogen pipe of the adsorption hydrogen storage device 14 with a fuel cell 16; step 7), connecting the anode and the cathode of the fuel cell with a load bulb 17; step 8), connecting the pressure sensor 3, the temperature sensor 4, the flowmeter 5, the power meter 18 and the like with the data acquisition instrument 19; step 9) adjusting a second height adjusting bracket 11; step 10), adjusting a frequency converter to adjust the wind speed; step 11), turning on a xenon lamp, and adjusting proper irradiation intensity; step 12) measuring and analyzing wind and light complementary power generation performance; step 13) measuring and analyzing the hydrogen production performance by electrolysis; step 14) measuring and analyzing the hydrogen storage performance; step 15) measuring and analyzing the performance of the fuel cell.
The foregoing embodiments may be modified in many different ways to achieve the same purpose, without departing from the spirit and scope of the invention, which is defined by the following claims.

Claims (7)

1. The utility model provides a hydrogen manufacturing fuel cell measures experimental apparatus based on wind-powered electricity generation which characterized in that includes: hydrogen fuel cell unit and wind power generation mechanism and photovoltaic power generation mechanism that links to each other respectively wherein: the loads of the wind power generation mechanism and the electrolytic hydrogen production device are provided with sensing detector combinations connected with a data acquisition instrument;
the sensing detector group comprises: the wind power generation system comprises a pressure sensor, a temperature sensor and a flowmeter which are arranged on the wind power generation mechanism and are respectively connected with a data acquisition instrument, and a power meter which is respectively connected with a load and the data acquisition instrument.
2. The experimental apparatus for measuring hydrogen production fuel cell based on wind power as claimed in claim 1, wherein the wind power generation mechanism comprises: tuber pipe, set up in axial fan and aerogenerator at its both ends, wherein: the wind driven generator is movably arranged, and the output end of the wind driven generator is connected with the electrolytic hydrogen production device.
3. The experimental apparatus for measuring hydrogen production fuel cell based on wind power as claimed in claim 2, wherein an air distributor is arranged on one side of the air pipe close to the axial flow fan to output a more uniform wind field.
4. The experimental device for measuring hydrogen production fuel cells based on wind power as claimed in claim 2 or 3, wherein the axial flow fan is connected with a frequency converter, and the wind speed is adjusted by adjusting the output frequency of the frequency converter.
5. The experimental apparatus for measuring hydrogen production fuel cell based on wind power as claimed in claim 1, wherein the photovoltaic power generation mechanism comprises: photovoltaic board and xenon lamp that relative setting, wherein: the output end of the photovoltaic panel is connected with the electrolytic hydrogen production device, and the xenon lamp is movably arranged.
6. The experimental device for measuring hydrogen production fuel cells based on wind power generation as claimed in claim 5, wherein the xenon lamp is arranged on the second height-adjusting bracket to adjust the position between the xenon lamp and the photovoltaic panel so as to control the irradiation intensity.
7. The experimental apparatus for measuring hydrogen production fuel cell based on wind power as claimed in claim 1, wherein the hydrogen fuel cell unit comprises: electrolytic water hydrogen production device, adsorption hydrogen storage device and fuel cell that connect gradually, wherein: the output end of the fuel cell is provided with a load.
CN202220030981.4U 2022-01-07 2022-01-07 Hydrogen production fuel cell measurement experimental device based on wind power Active CN217789312U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202220030981.4U CN217789312U (en) 2022-01-07 2022-01-07 Hydrogen production fuel cell measurement experimental device based on wind power

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202220030981.4U CN217789312U (en) 2022-01-07 2022-01-07 Hydrogen production fuel cell measurement experimental device based on wind power

Publications (1)

Publication Number Publication Date
CN217789312U true CN217789312U (en) 2022-11-11

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CN202220030981.4U Active CN217789312U (en) 2022-01-07 2022-01-07 Hydrogen production fuel cell measurement experimental device based on wind power

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CN (1) CN217789312U (en)

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