KR101231088B1 - Fuel cell power generation experimental apparatus using hydrogen and experimental method thereof - Google Patents

Abstract

In the present invention, the amount of hydrogen supplied to the electrolytic cell is measured in the process of generating hydrogen in the electrolytic cell using electricity and generating hydrogen by supplying the generated hydrogen to the fuel cell, The present invention relates to an apparatus and a method for testing a fuel cell power generation system using hydrogen to measure the amount of hydrogen supplied to the fuel cell and measure the amount of power generated in the fuel cell according to the hydrogen consumption amount.

Description

TECHNICAL FIELD [0001] The present invention relates to a fuel cell power generation system using hydrogen,

The present invention relates to an apparatus and a method for testing a fuel cell power generation using hydrogen, and more particularly, to an apparatus and method for generating electricity by using hydrogen to generate electricity in an electrolytic cell, The amount of hydrogen generated according to the amount of water consumed and the amount of hydrogen supplied to the fuel cell are measured, and the amount of hydrogen fuel consumed by the fuel cell, which can measure the amount of power generated by the fuel cell according to the amount of hydrogen consumed, The present invention relates to an apparatus and an apparatus for testing a battery.

Generally, a fuel cell (fuel cell) is a cell that converts chemical energy generated by the oxidation of fuel (hydrogen, LNG, LPG, etc.) directly into electrical energy. It is low-pollution, Heat) can be utilized, hydrogen-air fuel cells using hydrogen gas as a main component and oxygen in the air having high efficiency as a whole are being used.

The fuel cell, which obtains an electromotive force by the electrochemical reaction between hydrogen and oxygen as described above, needs a hydrogen generator for changing the gas (gas) containing a large amount of hydrogen required by the fuel cell in order to generate electrons at the anode .

On the other hand, the elementary school includes the experiment to generate hydrogen for the students, and the advanced educational institutes such as high schools and universities are equipped with the fuel cell basic experiment equipment using hydrogen to separate water from water using water, We are also experimenting with generating hydrogen by supplying separated hydrogen to fuel cells.

However, the conventional fuel cell power generation experiment apparatus using hydrogen as described above is merely an experiment for generating hydrogen and supplying it to the fuel cell to generate electric power, so that it is difficult to expect a great educational effect.

In addition, the fuel cell power generation experimental apparatus described above can not accurately measure the amount of water consumed for generating hydrogen, and can not measure the power consumed.

In addition, it is difficult to measure the hydrogen generation amount generated in the hydrogen generator and the hydrogen consumption amount consumed in the fuel cell, and it is difficult to measure the consumption voltage and the power amount of the fuel cell according to the hydrogen consumption amount, And the power consumption of the fuel cell.

Therefore, the conventional fuel cell power generation test does not shorten the test time, and it is difficult to derive accurate test data. Since the efficiency of the entire test is limited, the actual reliability of the use And satisfaction were minimized.

In order to solve the above problems, the present invention measures the amount of electric power supplied to an electric electrolytic cell in the process of generating hydrogen in an electric electrolytic cell by using electricity through the experiment and supplying the generated hydrogen to the fuel cell to generate electric power The present invention provides a fuel cell power generation experiment apparatus and a test method using the hydrogen that can measure the amount of hydrogen generation according to the consumption amount of water and the hydrogen consumption amount supplied to the fuel cell and measure the amount of power generated from the fuel cell according to the hydrogen consumption amount It has its purpose.

In addition, the present invention can repeatedly and quickly perform the same experiment repeatedly considering the reproducibility of the experiment, can shorten the experiment time more efficiently than the conventional experimental methods, and can create an experimental environment in which accurate experimental results can be obtained It is an object of the present invention to provide a fuel cell power generation experimental apparatus using hydrogen and an experimental method thereof

In the present invention, water is supplied from a water tank to separate hydrogen from the electrolytic cell first, separated into gaseous hydrogen secondarily in a gaseous hydrogen separator, and then moisture contained in the gaseous hydrogen is adsorbed in a water adsorber to supply the fuel cell with high purity The present invention also provides a fuel cell power generation system capable of generating hydrogen in a fuel cell.

It is another object of the present invention to provide a fuel cell power generation experiment apparatus using hydrogen, which can prevent a safety accident by discharging the hydrogen remaining inside the hydrogen transfer pipe to the outside after the completion of the experiment.

According to an aspect of the present invention, there is provided an apparatus for testing fuel cell power generation using hydrogen,

A water tank 110 having a flow rate reading scale 111 for storing purified water by cooling water vapor generated by heating water, and for checking the amount of water stored in the front side of the water tank 110;

A plurality of electric electrolytic baths 130 for supplying water in the watertank 110 through the water transfer pipe 120 and separating hydrogen from water and returning water to the watertank 110;

A plurality of electrolytic cells 130 for separating hydrogen from the water contained in the hydrogen supplied through the hydrogen transfer pipe 140 by electricity and returning the separated water to the water bottle 110 A gaseous hydrogen separator 150;

A plurality of water adsorbing units 160 for supplying gaseous hydrogen separated from the gaseous hydrogen separator 150 through a hydrogen transfer pipe 140 to adsorb moisture contained in gaseous hydrogen to separate high purity hydrogen;

A fuel cell 170 for supplying hydrogen from the water adsorber 160 through the hydrogen transfer pipe 140 to convert chemical energy of hydrogen into electric energy to produce electric power;

An instrument panel 180 for supplying electric power to the electric electrolytic bath 130 and the gas-hydrogen separator 150, and displaying electric power to be supplied and electric power generated from the fuel cell 170;

And a plurality of luminescent lamps 190 that emit light by being supplied with power from the fuel cell 170 so that the power generated by the fuel cell 170 can be visually confirmed.

A hydrogen supply control valve 200 provided in the hydrogen transfer pipe 140 between the water adsorber 160 and the fuel cell 170 to regulate the amount of hydrogen supplied to the fuel cell 170 and the water adsorber 160 The hydrogen separator 150 and the water adsorber 160 after the test is completed in the hydrogen transfer pipe 140 between the hydrogen transfer pipe 140 and the fuel cell 170 and the hydrogen transfer pipe 140 between the hydrogen transfer pipe 140 and the electrolytic cell 130, And a hydrogen discharge valve (210) for discharging hydrogen into the air.

A hydrogen pressure gauge 220 provided in the hydrogen transfer pipe 140 between the water adsorber 160 and the fuel cell 170 for indicating the pressure of hydrogen transferred into the hydrogen transfer pipe 140, When the hydrogen pressure inside the hydrogen transfer pipe 140 reaches a predetermined pressure when the hydrogen transfer pipe 140 between the hydrogen transfer pipe 160 and the fuel cell 170 reaches a predetermined pressure, And a hydrogen pressure switch 230 for opening / closing the power of the separator 150.

The instrument panel 180 includes a main switch 181 for initially supplying electricity to the instrument panel 180;

An electrolytic cell power switch 182 for turning on / off power to the electrolytic cell 130;

An electrolytic cell voltage display unit 183 for displaying the voltage of the electric power supplied to the electric electrolytic cell 130 in numerical values;

An electrolytic cell current display unit 184 for displaying a current of electric power supplied to the electrolytic cell 130 in numerical values;

A hydrogen generation amount display unit 185 for displaying the amount of hydrogen supplied to the fuel cell 170 in the water adsorbing unit 160 as a numerical value;

A fuel cell power switch 186 for turning on / off the power generated by the fuel cell 170;

A fuel cell voltage display unit 187 for displaying the voltage of the power generated by the fuel cell 170 in numerical values;

A fuel cell current display unit 188 for displaying the current of the power generated by the fuel cell 170 in numerical values;

And a plurality of lamp switches 189 for selectively supplying power to the plurality of light emitting lamps 190 according to the amount of power generated in the fuel cell 170.

Meanwhile, in the fuel cell power generation experiment method using hydrogen,

The switch of the instrument panel 180 is operated to apply power to the electrolytic cell 130 so that the water in the watertank 110 is supplied from the electrolytic bath 130 through the water transfer tube 120 and the hydrogen is firstly separated from the water , Returning the water to the water tank (110) again;

In the electrolytic cell 130, hydrogen is separated again from the water contained in the hydrogen by the electricity in the gaseous hydrogen separator 150 supplied with hydrogen through the hydrogen transfer pipe 140, Returning to the water tank (110);

The gaseous hydrogen separated from the gaseous hydrogen separator 150 is supplied to the water adsorbing unit 160 through the hydrogen transfer pipe 140 to adsorb moisture contained in the gaseous hydrogen and separate the gaseous hydrogen into high purity hydrogen;

And supplying hydrogen to the fuel cell 170 through the hydrogen transfer pipe 140 in the water adsorber 160 to convert chemical energy of hydrogen into electric energy to produce electric power.

As described above, the present invention provides an apparatus and method for testing a fuel cell using hydrogen, and a method for controlling the same in an electrolytic cell in a process of generating hydrogen in an electrolytic cell using electricity and supplying generated hydrogen to a fuel cell, The amount of hydrogen supplied to the fuel cell and the amount of hydrogen supplied to the fuel cell are measured and the amount of power generated by the fuel cell according to the amount of hydrogen consumed can be measured.

In addition, the present invention can repeatedly and quickly perform the same experiment repeatedly considering the reproducibility of the experiment, can shorten the experiment time more efficiently than the conventional experimental methods, and can create an experimental environment in which accurate experimental results can be obtained Be effective

In the present invention, water is supplied from a water tank to separate hydrogen from the electrolytic cell first, separated into gaseous hydrogen secondarily in a gaseous hydrogen separator, and then moisture contained in the gaseous hydrogen is adsorbed in a water adsorber to supply the fuel cell with high purity Of hydrogen can be generated.

Further, the present invention has the effect of preventing the safety accident by discharging the hydrogen remaining inside the hydrogen transfer pipe to the outside after the completion of the experiment.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary view showing a fuel cell power generation experiment apparatus using hydrogen according to the present invention. FIG.
BACKGROUND OF THE INVENTION Field of the Invention [0001]
3 is a front view of a fuel cell power generation experiment apparatus using hydrogen according to the present invention.
4 is a diagram illustrating an instrument panel of a fuel cell power generation experiment apparatus using hydrogen according to the present invention.
FIG. 5 is a view showing an example of a water and a hydrogen transfer path in a fuel cell power generation experiment apparatus using hydrogen according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 3, the apparatus for testing fuel cell power generation using hydrogen according to the present invention comprises: a table for heating purified water to cool water vapor generated by heating water to collect purified water; A water tank 110 having a flow rate reading scale 111 is provided so as to confirm the amount of water and water of the water tank 110 is supplied through the water transfer pipe 120 to primarily remove hydrogen from water, The water is provided with a plurality of electric electrolytic baths (130) for returning water to the water basin (110).

The water contained in the hydrogen supplied from the electrolytic cell 130 through the hydrogen transfer pipe 140 is separated again by electricity and the separated water is returned to the water bottle 110 again And a gaseous hydrogen separator 150 for separating the gaseous hydrogen separated from the gaseous hydrogen separator 150. The gaseous hydrogen separated from the gaseous hydrogen separator 150 is supplied through the hydrogen transfer pipe 140 to adsorb moisture contained in gaseous hydrogen, And a fuel cell 170 for supplying hydrogen from the water adsorber 160 through the hydrogen transfer pipe 140 and converting chemical energy of hydrogen into electric energy to produce electric power do.

An instrument panel 180 for supplying electric power to the electric electrolytic bath 130 and the gas-hydrogen separator 150 and for displaying electric power to be supplied and electric power generated from the fuel cell 170, A plurality of luminescent lamps 190 are provided to supply power to the fuel cell 170 so that power can be visually confirmed.

4, the instrument panel 180 includes a main switch 181 for initially supplying electricity to the instrument panel 180 and includes an electrolytic cell power switch 182 for turning on / off the power to the electrolytic cell 130 And an electrolytic cell voltage display unit 183 for displaying the voltage of the electric power supplied to the electrolytic cell 130 in numerical values and an electrolytic cell current display unit for displaying the current of the electric power supplied to the electrolytic cell 130 in numerical values 184 are provided.

And a hydrogen generation amount display unit 185 for indicating the amount of hydrogen supplied to the fuel cell 170 in the water adsorption unit 160. The fuel cell power switch 170 switches on / And a fuel cell voltage display unit 187 for displaying the voltage of the power generated by the fuel cell 170 in numerical values, A battery current display unit 188 is provided.

And a plurality of lamp switches 189 for selectively supplying electric power to the plurality of light emitting lamps 190 according to the amount of electric power generated in the fuel cell 170.

 1 to 3, the hydrogen transfer pipe 140 between the water adsorber 160 and the fuel cell 170 is provided with a hydrogen supply control valve 200 (see FIG. 1) for controlling the amount of hydrogen supplied to the fuel cell 170, And the hydrogen transfer pipe 140 between the water adsorber 160 and the fuel cell 170 is connected to the hydrogen transfer pipe 140 and the electrolytic cell 130, the gas hydrogen separator 150, And a hydrogen discharge valve 210 for discharging hydrogen remaining in the adsorber 160 into the air.

The hydrogen transfer pipe 140 between the moisture adsorber 160 and the fuel cell 170 is provided with a hydrogen pressure gauge 220 indicating the pressure of hydrogen transferred into the hydrogen transfer pipe 140, When the hydrogen pressure inside the hydrogen transfer pipe 140 reaches a predetermined pressure, the hydrogen transfer pipe 140 between the adsorber 160 and the fuel cell 170 is connected to the electrolytic cell 130 and the gas- A hydrogen pressure switch 230 for opening and closing the power source of the fuel cell 150 is provided.

The experimental method of the fuel cell power generator using hydrogen according to the present invention will be described in detail as follows.

4 and 5, when an operator operates the main switch 181 of the instrument panel 180, electricity is first applied to the instrument panel 180, and when the operator operates the electrolytic cell power switch 182, The water in the water tank 110 is supplied from the electric electrolytic tank 130 through the water transfer pipe 120 by separating the hydrogen from the water and the remaining water is separated from the water tank 110).

At this time, it is preferable that the water in the water tank 110 supplied to the electric electrolytic bath 130 is heated to cool the evaporated water vapor to supply water such as purified distilled water. The electric electrolytic bath 130 may be a plurality You can experiment by installing a dog.

When power is supplied to the electrolytic cell 130, the experimenter checks the amount of power supplied to the electrolytic cell 130 through the electrolytic cell voltage display unit 183 of the instrument panel 180 and the electrolytic cell current display unit 184.

The hydrogen separated from the electrolytic cell 130 is supplied to the gaseous hydrogen separator 150 through the hydrogen transfer pipe 140. The hydrogen supplied to the gaseous hydrogen separator 150 is supplied to the electrolytic cell 130 It is supplied completely with hydrogen and water without mixing.

In the gaseous hydrogen separator 150, the water contained in the hydrogen is separated into hydrogen again in a gaseous state by electricity, and the separated water is returned to the water tank 110 again.

The gaseous hydrogen separated from the gaseous hydrogen separator 150 is supplied to the plurality of water adsorption units 160 through the hydrogen transfer pipe 140 to thereby adsorb moisture contained in the gaseous hydrogen while talking to the water adsorption unit 160 Only high purity hydrogen is separated.

When the power is applied by operating the fuel cell power switch 186 of the instrument panel 180, hydrogen is supplied from the moisture adsorber 160 to the fuel cell 170 through the hydrogen feed pipe 140, Energy is converted into electric energy to produce electric power.

At this time, the experimenter measures the amount of hydrogen supplied to the fuel cell 170 from the water adsorption unit 160 through the hydrogen generation amount display unit 185 of the instrument panel 180, numerically measures the electric power generated from the fuel cell 170, Through the battery voltage display unit 187 and the fuel cell current display unit 188. [

As described above, the experimenter measures the consumption amount of water through the flow rate reading scale 111 of the water bottle 110 while measuring the hydrogen generation amount and the electric power amount of the fuel cell 170.

Also, according to the amount of power generated in the fuel cell 170, the experimenter operates the plurality of lamp switches 189 on the instrument panel 180 to selectively supply power to the plurality of luminescent lamps 190, Power can be visually confirmed.

On the other hand, the experimenter adjusts the amount of hydrogen supply control valve 200 provided in the hydrogen transfer pipe 140 between the water adsorber 160 and the fuel cell 170 to adjust the amount of hydrogen supplied to the fuel cell 170 The amount of hydrogen in the fuel cell 170 can be measured.

The experimenter can measure the pressure of hydrogen transferred into the hydrogen transfer pipe 140 through the hydrogen pressure gauge 220 provided in the hydrogen transfer pipe 140 between the moisture adsorber 160 and the fuel cell 170 .

The hydrogen pressure switch 230 provided in the hydrogen transfer pipe 140 between the moisture adsorber 160 and the fuel cell 170 is connected to the hydrogen supply pipe 140 when the hydrogen pressure inside the hydrogen transfer pipe 140 reaches a predetermined pressure. 180 to automatically open and close the power source of the electrolytic cell 130 and the gas-hydrogen separator 150 to prevent a safety accident in advance.

When the experiment is completed, the experimenter opens the hydrogen discharge valve 210 provided in the hydrogen transfer pipe 140 between the water adsorber 160 and the fuel cell 170 and connects the hydrogen transfer pipe 140 and the electrolytic cell 130, The hydrogen remaining in the gaseous hydrogen separator 150 and the water adsorber 160 is discharged into the air to prevent a safety accident in advance and thus the experiment can be safely terminated.

In the fuel cell power generation experiment apparatus using hydrogen, the amount of power supplied to the electrolytic cell is measured in the process of generating hydrogen in the electrolytic cell and supplying the generated hydrogen to the fuel cell to generate electric power, , The amount of hydrogen generated according to the amount of water consumed and the amount of hydrogen supplied to the fuel cell are measured and the amount of power generated by the fuel cell according to the amount of hydrogen consumption can be measured and the same experiment can be repeatedly performed in consideration of the reproducibility of the experiment In addition, it is possible to shorten the experiment time more efficiently than the conventional experimental methods, and to create an experimental environment for obtaining accurate experimental results

In the present invention, water is supplied from a water tank to separate hydrogen from the electrolytic cell first, separated into gaseous hydrogen secondarily in a gaseous hydrogen separator, and then moisture contained in the gaseous hydrogen is adsorbed in a water adsorber to supply the fuel cell with high purity Of hydrogen can be generated.

100: Fuel cell power generation experiment device
110: Bucket 111: Flow record scale
120: water transfer pipe 130: electric electrolytic cell
140: hydrogen transfer pipe 150:
160: Water adsorber 170: Fuel cell
180: Instrument panel 181: Main switch
182: electrolytic cell power switch 183: electrolytic cell voltage display
184: electrolytic cell current display part 185: hydrogen generation amount display part
186: fuel cell power switch 187: fuel cell voltage indicator
188: fuel cell current display unit 189: lamp switch
190: Luminescent lamp 200: Water supply regulating valve
210: hydrogen discharge valve 220: hydrogen pressure gauge
230: Hydrogen pressure switch

Claims (7)

In a fuel cell power generation experiment apparatus using hydrogen,
A water tank 110 having a flow rate reading scale 111 for storing purified water by cooling water vapor generated by heating water, and for checking the amount of water stored in the front side of the water tank 110;
A plurality of electric electrolytic baths 130 for supplying water in the watertank 110 through the water transfer pipe 120 and separating hydrogen from water and returning water to the watertank 110;
A plurality of electrolytic cells 130 for separating hydrogen from the water contained in the hydrogen supplied through the hydrogen transfer pipe 140 by electricity and returning the separated water to the water bottle 110 A gaseous hydrogen separator 150;
A plurality of water adsorbing units 160 for supplying gaseous hydrogen separated from the gaseous hydrogen separator 150 through a hydrogen transfer pipe 140 to adsorb moisture contained in gaseous hydrogen to separate high purity hydrogen;
A fuel cell 170 for supplying hydrogen from the water adsorber 160 through the hydrogen transfer pipe 140 to convert chemical energy of hydrogen into electric energy to produce electric power;
An instrument panel 180 for supplying electric power to the electric electrolytic bath 130 and the gas-hydrogen separator 150, and displaying electric power to be supplied and electric power generated from the fuel cell 170;
And a plurality of luminescent lamps (190) which are powered by the fuel cell (170) and emit light so that the power generated by the fuel cell (170) can be visually confirmed. The fuel cell system according to claim 1, further comprising a hydrogen supply control valve (200) provided in the hydrogen transfer pipe (140) between the water adsorber (160) and the fuel cell (170) to regulate the amount of hydrogen supplied to the fuel cell Wherein the fuel cell is a hydrogen fuel cell. 2. The fuel cell system according to claim 1, wherein the hydrogen transfer pipe (140) is provided between the water adsorber (160) and the fuel cell (170) and the hydrogen transfer pipe (140), the electrolytic cell (130) And a hydrogen discharge valve 210 for discharging the hydrogen remaining in the water adsorber 160 into the air. The hydrogen pressure gauge (220) for indicating the pressure of hydrogen delivered to the inside of the hydrogen transfer pipe (140), which is provided in the hydrogen transfer pipe (140) between the moisture adsorber (160) and the fuel cell Wherein the fuel cell is a hydrogen fuel cell. The fuel cell system according to claim 1, wherein when the hydrogen pressure inside the hydrogen transfer pipe (140) reaches a predetermined pressure in the hydrogen transfer pipe (140) between the water adsorber (160) And a hydrogen pressure switch (230) for opening and closing a power source of the electrolytic cell (130) and the gas hydrogen separator (150). The apparatus of claim 1, wherein the instrument panel (180) comprises a main switch (181) for first supplying electricity to the instrument panel (180);
An electrolytic cell power switch 182 for turning on / off power to the electrolytic cell 130;
An electrolytic cell voltage display unit 183 for displaying the voltage of the electric power supplied to the electric electrolytic cell 130 in numerical values;
An electrolytic cell current display unit 184 for displaying a current of electric power supplied to the electrolytic cell 130 in numerical values;
A hydrogen generation amount display unit 185 for displaying the amount of hydrogen supplied to the fuel cell 170 in the water adsorbing unit 160 as a numerical value;
A fuel cell power switch 186 for turning on / off the power generated by the fuel cell 170;
A fuel cell voltage display unit 187 for displaying the voltage of the power generated by the fuel cell 170 in numerical values;
A fuel cell current display unit 188 for displaying the current of the power generated by the fuel cell 170 in numerical values;
And a plurality of lamp switches (189) for selectively supplying power to the plurality of light emitting lamps (190) according to an amount of power generated in the fuel cell (170). In a fuel cell power generation test method using hydrogen,
The switch of the instrument panel 180 is operated to apply power to the electrolytic cell 130 so that the water in the watertank 110 is supplied from the electrolytic bath 130 through the water transfer tube 120 and the hydrogen is firstly separated from the water , Returning the water to the water tank (110) again;
In the electrolytic cell 130, hydrogen is separated again from the water contained in the hydrogen by the electricity in the gaseous hydrogen separator 150 supplied with hydrogen through the hydrogen transfer pipe 140, Returning to the water tank (110);
The gaseous hydrogen separated from the gaseous hydrogen separator 150 is supplied to the water adsorbing unit 160 through the hydrogen transfer pipe 140 to adsorb moisture contained in the gaseous hydrogen and separate the gaseous hydrogen into high purity hydrogen;
And supplying hydrogen to the fuel cell (170) through the hydrogen transfer pipe (140) in the water adsorber (160) to convert the chemical energy of hydrogen into electric energy to produce electric power. Fuel cell power generation test method.

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