CN204596293U - Hydrogen Energy experimental provision - Google Patents
Hydrogen Energy experimental provision Download PDFInfo
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- CN204596293U CN204596293U CN201520190020.XU CN201520190020U CN204596293U CN 204596293 U CN204596293 U CN 204596293U CN 201520190020 U CN201520190020 U CN 201520190020U CN 204596293 U CN204596293 U CN 204596293U
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Abstract
The utility model provides a kind of Hydrogen Energy experimental provision, comprising: electrolytic module, is provided with electrolysis power jack, electrolysis hydrogen venthole, electrolysis hydrogen inlet opening, electrolytic oxygen venthole and electrolytic oxygen inlet opening; Hydrogen collecting apparatus, be provided be communicated with electrolysis hydrogen venthole hydrogen gas hole, hydrogen exhaust hole, hydrogen volume scale, the first distilled water ordinary water level and the first row water hole that is communicated with electrolysis hydrogen inlet opening; Oxygen gatherer, be provided be communicated with electrolysis hydrogen venthole hydrogen gas hole, oxygen vent port, oxygen volume markings, after-fractionating water ordinary water level and the second row water hole that is communicated with electrolytic oxygen inlet opening; Pressure regulator, the electrolysis be provided with for being electrically connected electrolysis power jack connects jack, for changing adjusting pressuring knob and the voltage controller power source jack of output voltage; Timer.The utility model, by combining various relevant with the Hydrogen Energy experiment equipment provided, solves the problem lacked about the experiment device for teaching of Hydrogen Energy.
Description
Technical field
The utility model relates to energy instructional technology field, is specifically related to a kind of Hydrogen Energy experimental provision.
Background technology
Hydrogen Energy is the energy produced by hydrogen and oxygen reaction.Hydrogen Energy is the chemical energy of hydrogen, and hydrogen is main on earth to be occurred with the form of chemical combination state, is the material the most widely that distributes in universe, it constitutes 75% of mass of the universe, secondary energy.The major advantage of Hydrogen Energy has: combustion heat value is high, and the heat after the burning of every kg of hydrogen, is about 3 times of gasoline, 3.9 times of alcohol, 4.5 times of coke.The product of burning is water, is the energy the cleanest in the world.Aboundresources, hydrogen can be produced by water, and water is rich in natural resources the most on the earth, and having deduced, natural material recycles, the classical processes of sustainable development.
Although the exploitation of Hydrogen Energy is more and more subject to people's attention, in teaching process, but lack the experiment device for teaching about Hydrogen Energy.
Utility model content
For overcoming the defect existing for prior art, now provide a kind of Hydrogen Energy experimental provision, to solve the problem lacked about the experiment device for teaching of Hydrogen Energy.
For achieving the above object, a kind of Hydrogen Energy experimental provision, comprising: electrolytic module, is provided with electrolysis power jack, electrolysis hydrogen venthole, electrolysis hydrogen inlet opening, electrolytic oxygen venthole and electrolytic oxygen inlet opening; Hydrogen collecting apparatus, be provided be communicated with described electrolysis hydrogen venthole hydrogen gas hole, hydrogen exhaust hole, hydrogen volume scale, the first distilled water ordinary water level and the first row water hole that is communicated with described electrolysis hydrogen inlet opening; Oxygen gatherer, be provided be communicated with described electrolysis hydrogen venthole hydrogen gas hole, oxygen vent port, oxygen volume markings, after-fractionating water ordinary water level and the second row water hole that is communicated with described electrolytic oxygen inlet opening; Pressure regulator, the electrolysis be provided with for being electrically connected described electrolysis power jack connects jack, for changing adjusting pressuring knob and the voltage controller power source jack of output voltage; And timer.
The further improvement of the utility model Hydrogen Energy experimental provision is, also comprises: be connected to the reometer between described electrolytic module and described pressure regulator.
The further improvement of the utility model Hydrogen Energy experimental provision is, also comprises: the voltage table in parallel with described electrolytic module.
The further improvement of the utility model Hydrogen Energy experimental provision is, also comprise: electricity generation module, be provided with power generating source jack, the generating oxygen air admission hole be communicated with described oxygen vent port, the oxygen vent port that generates electricity, the generating hydrogen gas hole be communicated with described hydrogen exhaust hole and the hydrogen exhaust hole that generates electricity; For being electrically connected the first load of described electricity generation module, comprise motor, for being electrically connected the motor socket of described motor, bulb and the light bulb socket for being electrically connected described bulb.
The further improvement of the utility model Hydrogen Energy experimental provision is, also comprise: electricity generation module, be provided with power generating source jack, the generating oxygen air admission hole be communicated with described oxygen vent port, the oxygen vent port that generates electricity, the generating hydrogen gas hole be communicated with described hydrogen exhaust hole and the hydrogen exhaust hole that generates electricity; Second load, the generating comprised for connecting described power generating source jack connects jack, for the voltage socket of measuring voltage value, for measuring the current sockets of current value and the knob for adjusting resistance value; For being electrically connected the voltage table of described voltage socket; And for being electrically connected described current sockets reometer.
The further improvement of the utility model Hydrogen Energy experimental provision is, also comprises the first battery base for placing described electrolytic module, for placing the second battery base of described electricity generation module and the gas collector base for placing described hydrogen collecting apparatus and described oxygen gatherer.
The further improvement of the utility model Hydrogen Energy experimental provision is, described pressure regulator is also equipped with the power supply adaptor for being electrically connected described voltage controller power source jack.
The further improvement of the utility model Hydrogen Energy experimental provision is, also comprises the vent valve for connecting described hydrogen exhaust hole and described oxygen vent port.
The beneficial effects of the utility model are, by combining various relevant with the Hydrogen Energy experiment equipment provided, can realize the experimental modelling about Hydrogen Energy, thus solve the problem lacked about the experiment device for teaching of Hydrogen Energy.
Accompanying drawing explanation
Fig. 1 is the experiment schematic diagram of the hydrogen of checking brine electrolysis generation and the volume ratio of oxygen;
Fig. 2 is the experimental circuit in Fig. 1;
Fig. 3 is the experiment schematic diagram of the relation of gas volume and the electric current produced in the checking unit interval;
Fig. 4 is the experimental circuit in Fig. 3;
Fig. 5 is the experiment schematic diagram of the efficiency of research electrolysis unit;
Fig. 6 is the experimental circuit in Fig. 5;
Fig. 7 is the experiment schematic diagram of the efficiency of research Blast Furnace Top Gas Recovery Turbine Unit (TRT);
Fig. 8 is the experimental circuit in Fig. 7;
Fig. 9 is the experiment schematic diagram of the relation of research Blast Furnace Top Gas Recovery Turbine Unit (TRT) volt-ampere characteristic and power and electric current;
Figure 10 is the experimental circuit in Fig. 9;
Figure 11 is the experiment schematic diagram that Hydrogen Energy drives the first load;
Figure 12 is the experimental circuit in Figure 11;
Figure 13 is the experiment schematic diagram utilizing solar energy electrolyzing water;
Figure 14 is the experimental circuit in Figure 13;
Figure 15 is the experiment schematic diagram utilizing wind energy brine electrolysis;
Figure 16 is the experimental circuit in Figure 15.
Embodiment
For the benefit of to the understanding of structure of the present utility model, be described below in conjunction with drawings and Examples.
Please refer to Fig. 1, Fig. 1 is the experiment schematic diagram of the hydrogen of checking brine electrolysis generation and the volume ratio of oxygen.As shown in Figure 1, the utility model provides a kind of Hydrogen Energy experimental provision, comprising: electrolytic module 11, is provided with electrolysis power jack, electrolytic oxygen venthole, electrolytic oxygen inlet opening, electrolysis hydrogen venthole and electrolysis hydrogen inlet opening; Hydrogen collecting apparatus 21, is provided with first row water hole, hydrogen gas hole, hydrogen exhaust hole, the first distilled water ordinary water level and hydrogen volume scale; Oxygen gatherer 22, is provided with second row water hole, oxygen air admission hole, oxygen vent port, after-fractionating water ordinary water level and oxygen volume markings; Pressure regulator 3, the electrolysis be provided with for connecting described electrolysis power jack connects jack, for changing adjusting pressuring knob and the voltage controller power source jack of output voltage; Timer 4; For connecting the power supply adaptor of described voltage controller power source jack; Conduit 51; Vent valve 52.
Further, as seen in figs. 7 and 11, the utility model Hydrogen Energy experimental provision also comprises: for the universal metre 6 of measuring voltage and electric current; Electricity generation module 12, is provided with power generating source jack, generating oxygen air admission hole, generating oxygen vent port, generating hydrogen gas hole and generating hydrogen exhaust hole; First load 71, comprises motor 710, motor socket, bulb 711 and the light bulb socket for being electrically connected bulb 711 for electrical connection electric motor 710; Second load 72, comprise with electric loading, to connect for the generating being electrically connected described power generating source jack jack, for measuring voltage value voltage socket, for measure current value current sockets and for regulating the knob of the resistance value of described electric loading; For place electrolytic module 11 the first battery base 110, for placing the second battery base 120 of electricity generation module 12 and the gas collector base 23 for placing hydrogen collecting apparatus 21 and oxygen gatherer 22; For clamping the vessel clamp 510 of conduit 51.
During in order to test, test desktop clean and tidy, the utility model Hydrogen Energy experimental provision also comprises the Hydrogen Energy brassboard for depositing the first battery base 110, second battery base 120, gas collector base 23, timer 4, pressure regulator 3, universal metre 6, first load 71 and the second load 72.
As depicted in figs. 1 and 2, utilize the assembly in Fig. 1, the experiment of the hydrogen of checking brine electrolysis generation and the volume ratio of oxygen can be carried out, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110, timer 4, pressure regulator 3 are placed in the corresponding position of Hydrogen Energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, and hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, are connected by pressure regulator 3 with wire with electrolytic module 11;
3. utilize conduit 51 to be connected with the oxygen air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. utilize conduit 51 to be connected with the venthole of hydrogen collecting apparatus 21 with oxygen gatherer 22 respectively by two vent valves 52, connected as shown in Figure 1;
6., respectively to injecting distilled water in hydrogen collecting apparatus 21 and oxygen gatherer 22 to " water line " position, by pressing vent valve 52 distilled water injected the below (now distilled water fills gas collector inside) of gatherer;
7. power supply adaptor is connected with pressure regulator 3, rotates pressure regulator 3 to 2, and connect power supply, utilize timer 4 timing three minutes, the time arrives simultaneously, records the volume producing gas in two gas collectors, is recorded in experimental data table 1-1;
Table 1-1
| The gas produced | Produce the volume/ml (1ml=1cm of gas 3) |
| H 2 | |
| O 2 |
8. repeat above-mentioned experiment, record experimental data;
9. calculate the volume ratio that water electrolysis produces hydrogen and oxygen;
10. arrange experiment equipment.
As shown in Figure 3 and Figure 4, utilize the assembly in Fig. 3, the experiment of the relation of gas volume and the electric current produced in the checking unit interval can be carried out, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110, timer 4, pressure regulator 3, universal metre 6 are placed in the corresponding position of Hydrogen Energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, and hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, are connected by pressure regulator 3 with wire with electrolytic module 11, and universal metre 6 is arranged between electrolytic module 11 and pressure regulator 3;
3. the electrolytic oxygen venthole of electrolytic module 11 is connected with the oxygen air admission hole of oxygen gatherer 22 by conduit 51, and the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. utilize conduit 51 to be connected with the venthole of hydrogen collecting apparatus 21 with oxygen gatherer 22 respectively by two vent valves 52, assembled as shown in Figure 3;
6., respectively to injecting distilled water in hydrogen collecting apparatus 21 and oxygen gatherer 22 to " water line " position, by pressing vent valve 52 distilled water injected the below (now distilled water fills gas collector inside) of gatherer;
7. connect power supply adaptor, the current gear of 10A is transferred to by universal metre 6, by pressure regulator 3, electric current is transferred to 0.1A, timer 4 timing, simultaneously record start and at the end of the volume of gas in hydrogen collecting apparatus 21 and oxygen gatherer 22, insert in experimental data table 2-1;
Table 2-1
8. changed the size of electric current by pressure regulator 3, repeat above-mentioned experiment.
9. different electric current produces the volume delta V/t of gas in the data unit of account time by experiment.
10. Plotting data current time image by experiment.The volume of gas and the relation of electric current is produced in observation unit's time.
11. arrange experiment equipment.
As shown in Figure 5 and Figure 6, utilize the assembly in Fig. 5, the experiment of the efficiency of the electrolysis unit that can conduct a research, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110, timer 4, pressure regulator 3, universal metre 6 are placed in the relevant position of Hydrogen Energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, with wire, pressure regulator 3 is connected with electrolytic module 11, two universal metres 6 are provided, one of them universal metre 6 is arranged between electrolytic module 11 and pressure regulator 3 as reometer, and another universal metre 6 is in parallel with electrolytic module 11 as voltage table;
3. utilize conduit 51 to be connected with the oxygen air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. utilize conduit 51 to be connected with the venthole of hydrogen collecting apparatus 21 with oxygen gatherer 22 respectively by two vent valves 52;
6. inject distilled water to " water line " position respectively in hydrogen collecting apparatus 21 and oxygen gatherer 22, by pressing vent valve 52 distilled water being injected the below (now distilled water fills gas collector inside) of gatherer, having assembled as shown in Figure 5;
7. connect power supply adaptor, the universal metre 6 of parallel connection is adjusted to 20V gear, by pressure regulator 3, electric current is adjusted to 0.1A, record volume and the voltage table registration of hydrogen and oxygen before and after 5min;
8. regulate pressure regulator 3 that electric current is adjusted to 0.5A, record volume and the voltage table registration of hydrogen and oxygen before and after 2min;
9. data calculate the volume producing gas by experiment.And calculate the electric energy E producing these hydrogen consumptions
eland the theoretical ENERGY E consumed
ch;
10. by the energy (under the status of criterion) of water electrolysis consumption in the computing formula theory of computation;
11. calculate the electric energy of water electrolysis consumption by computing formula;
12. by experiment principle calculate the efficiency of electrolysis unit;
13. arrange experiment equipment.
It should be noted that the test utilizing Fig. 5 also can carry out the volt-ampere characteristic studying electrolysis unit, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110, timer 4, pressure regulator 3, universal metre 6 are placed in the relevant position of Hydrogen Energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, with wire, pressure regulator 3 is connected with electrolytic module 11, two universal metres 6 are provided, one of them universal metre 6 is arranged between electrolytic module 11 and pressure regulator 3 as reometer, and another universal metre 6 is in parallel with electrolytic module 11 as voltage table;
3. utilize conduit 51 to be connected with the second air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the first air admission hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. utilize conduit 51 to be connected with the venthole of hydrogen collecting apparatus 21 with oxygen gatherer 22 respectively by two vent valves 52;
6. inject distilled water to " water line " position respectively in hydrogen collecting apparatus 21 and oxygen gatherer 22, by pressing vent valve 52 distilled water being injected the below (now distilled water fills gas collector inside) of gatherer, having assembled as shown in Figure 5;
7. voltage table is adjusted to 20V gear, reometer is adjusted to 200mA gear;
8. connect power supply adaptor, reometer is adjusted to 20mA, records the registration of now voltage table and insert in experimental data table 3-1;
9. by pressure regulator 3, reometer is adjusted to 40mA, 60mA, 100mA, 200mA respectively, records corresponding voltage table registration and insert in experimental data table 3-1;
10. the range of reometer is changed to the gear of 10A, by pressure regulator, electric current is adjusted to 300mA, 400mA, 500mA respectively, record corresponding voltage table registration and insert in experimental data table 3-1;
11. experimentally Plotting data volt-ampere characteristic;
12. sum up the voltage-current relationship of electrolysis unit according to volt-ampere characteristic.
Table 3-1
| I/mA | 0 | 20 | 40 | 60 | 100 | 200 | 300 | 400 | 500 |
| U/V |
13. arrange experiment equipment.
As shown in Figure 7 and Figure 8, utilize the assembly in Fig. 7, the experiment of the efficiency of the Blast Furnace Top Gas Recovery Turbine Unit (TRT) that can conduct a research, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110, second battery base 120, timer 4, pressure regulator 3, universal metre 6, second load 72 are placed in the corresponding position of Hydrogen Energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, and electricity generation module 12 is arranged on the second battery base 120, and hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, are connected by pressure regulator 3 with wire with electrolytic module 11;
3. utilize conduit 51 to be connected with the oxygen air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. get two conduits 51, be each passed through vessel clamp 510, be connected with the generating hydrogen gas hole of electricity generation module 12 in the hydrogen exhaust hole of hydrogen collecting apparatus 21, the oxygen vent port of oxygen gatherer 22 is connected with the generating oxygen air admission hole of electricity generation module 12, closure catheter for closing folder 510;
6. be connected as voltage table with " U " two ends of the second load 72 by a universal metre 6, another universal metre 6 is connected with " I " two ends of the second load 72 as reometer, and the power hole of electricity generation module 12 is connected with " fuel cell " two ends of the second load 72;
7. two vent valves 52 are arranged on the generating oxygen vent port of electricity generation module 12 respectively and generate electricity on hydrogen exhaust hole, as shown in Figure 7;
8. inject distilled water to " water line " position respectively in hydrogen collecting apparatus 21 and oxygen gatherer 22, open vessel clamp 510, by pressing vent valve 52 distilled water injected the below (now distilled water fills gas collector inside) of gatherer, closure catheter for closing folder 510;
9. connect power supply adaptor, be adjusted to maximum by pressure regulator 3, until hydrogen collecting apparatus 21 is collected full (now hydrogen volume is 30ml), powered-down, opens vessel clamp 510;
10. voltage table is adjusted to 2000mV gear, reometer is adjusted to 10A gear, regulates the potentiometer of the second load 72, makes reometer be respectively 0.2A and 0.5A, record the time of corresponding magnitude of voltage and experiment and consume the volume of hydrogen, being filled up in experimental data table 4-1;
Table 4-1
The efficiency of 11. electricity generation modules 12 equals the ratio of electric energy and the chemical energy stored by hydrogen produced;
12. calculate by computing formula the electric energy produced;
13. calculate the chemical energy (under the status of criterion) stored by hydrogen by computing formula;
14. by experiment principle calculate the efficiency of generating battery device;
15. arrange experiment equipment.
As shown in Figure 9 and Figure 10, utilize the assembly in Fig. 9, the experiment of the relation of the Blast Furnace Top Gas Recovery Turbine Unit (TRT) that can conduct a research volt-ampere characteristic and power and electric current, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110, second battery base 120, timer 4, pressure regulator 3, universal metre 6, second load 72 are placed in the corresponding position of Hydrogen Energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, and electricity generation module 12 is arranged on the second battery base 120, and hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, are connected by pressure regulator 3 with wire with electrolytic module 11;
3. utilize conduit 51 to be connected with the oxygen air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. get two conduits 51, be each passed through vessel clamp 510, be connected with the generating hydrogen gas hole of electricity generation module 12 in the hydrogen exhaust hole of hydrogen collecting apparatus 21, the oxygen vent port of oxygen gatherer 22 is connected with the generating oxygen air admission hole of electricity generation module 12, closure catheter for closing folder 510;
6. be connected as voltage table with " U " two ends of the second load 72 by a universal metre 6, another universal metre 6 is connected with " I " two ends of the second load 72 as reometer, and the power hole of electricity generation module 12 is connected with " fuel cell " two ends of the second load 72;
7. two vent valves 52 are arranged on the generating oxygen vent port of electricity generation module 12 respectively and generate electricity on hydrogen exhaust hole, as shown in Figure 9, distilled water is injected to " water line " position respectively in hydrogen collecting apparatus 21 and oxygen gatherer 22, open vessel clamp 510, by pressing vent valve 52 distilled water injected the below (now distilled water fills gas collector inside) of gatherer, closure catheter for closing folder 510;
8. connect power supply adaptor, voltage table is adjusted to 20V gear, reometer is adjusted to 10A gear;
9. closure catheter for closing folder 510, connects power supply adaptor, powered-down after Hydrogen collection is full;
10. open vessel clamp 510, by the potentiometer of the second load 72, reometer is adjusted to 0A, 0.2A, 0.4A, 0.6A, 0.8A, 1.0A, 1.2A, 1.4A, 1.6A, 1.8A respectively, record corresponding voltage table registration in table 5-1;
Table 5-1
| I/A | 0.0 | 0.2 | 0.4 | 0.6 | 0.8 | 1.0 | 1.2 | 1.4 | 1.6 | 1.8 |
| U/V | ||||||||||
| P/W |
11. experimentally Plotting data volt-ampere characteristic and P/I curve, sum up experiment conclusion;
12. arrange experiment equipment.
As is illustrated by figs. 11 and 12, utilize the assembly in Figure 11, the experiment that Hydrogen Energy drives the first load can be carried out, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110, second battery base 120, pressure regulator 3, first load 71 are placed in the corresponding position of Hydrogen Energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, and electricity generation module 12 is arranged on the second battery base 120, and hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, are connected by pressure regulator 3 with wire with electrolytic module 11;
3. utilize conduit 51 to be connected with the oxygen air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. get two conduits 51, be each passed through vessel clamp 510, be connected with the generating hydrogen gas hole of electricity generation module 12 in the hydrogen exhaust hole of hydrogen collecting apparatus 21, the oxygen vent port of oxygen gatherer 22 is connected with the generating oxygen air admission hole of electricity generation module 12, closure catheter for closing folder 510;
6. two vent valves 52 are arranged on the generating oxygen vent port of electricity generation module 12 respectively and generate electricity on hydrogen exhaust hole, as shown in figure 11, distilled water is injected to " water line " position respectively in hydrogen collecting apparatus 21 and oxygen gatherer 22, open vessel clamp 510, by pressing vent valve 52 distilled water injected the below (now distilled water fills gas collector inside) of gatherer, closure catheter for closing folder 510;
7. be connected with electricity generation module 12 by pressure regulator 3 with wire, the motor 710 of the first load 71 is connected with electricity generation module 12 two ends, as shown in figure 11;
8. whether connect power supply adaptor, be adjusted to maximum by pressure regulator 3, until hydrogen collecting apparatus 21 is collected full (now hydrogen volume is 30ml), powered-down, opens vessel clamp 510, observe motor 710 and rotate;
9. closure catheter for closing folder 510, by the wire changing-over on motor 710 at bulb 711 two ends, opens conduit 510 and presss from both sides, and whether luminously observes bulb 711;
10. arrange experiment equipment.
As shown in Figure 13 and Figure 14, utilize the assembly in Figure 13, can the experiment of application solar energy electrolyzing water, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110 is placed in the corresponding position of Hydrogen Energy brassboard, solar energy equipment 81 and light source 82 are arranged on sun power brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, and hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, is connected by electrolytic module 11 with wire with solar energy equipment 81 (four groups of solar panels are connected);
3. utilize conduit 51 to be connected with the oxygen air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. utilize conduit 51 to be connected with the venthole of hydrogen collecting apparatus 21 with oxygen gatherer 22 respectively by two vent valves 52, connected as shown in figure 13;
6., respectively to injecting distilled water in hydrogen collecting apparatus 21 and oxygen gatherer 22 to " water line " position, by pressing vent valve 52 distilled water injected the below (now distilled water fills gas collector inside) of gatherer;
7. the solar panels of power supply adaptor with solar energy equipment 81 are connected, regulator potentiometer, open light source 82;
8. whether observe in hydrogen collecting apparatus 21 and oxygen gatherer 22 has gas to produce;
9. arrange experiment equipment.
As shown in Figure 15 and Figure 16, utilize the assembly in Figure 15, can the experiment of application wind energy brine electrolysis, can be undertaken by following experimental procedure:
1. gas collector base 23, first battery base 110 is placed in the corresponding position of Hydrogen Energy brassboard, is installed on aerogenerator 91 with screwdriver by flabellum 90, blower fan 92, fan housing and aerogenerator 92 is arranged on wind energy brassboard;
2. electrolytic module 11 is arranged on the first battery base 110, and hydrogen collecting apparatus 21 and oxygen gatherer 22 are arranged on gas collector base 23, are connected by electrolytic module 11 with wire with aerogenerator 91;
3. utilize conduit 51 to be connected with the oxygen air admission hole of oxygen gatherer 22 by the electrolytic oxygen venthole of electrolytic module 11, the electrolytic oxygen inlet opening of electrolytic module 11 is connected with the second row water hole of oxygen gatherer 22;
4. utilize conduit 51 to be connected with the hydrogen gas hole of hydrogen collecting apparatus 21 by the electrolysis hydrogen venthole of electrolytic module 11, the electrolysis hydrogen inlet opening of electrolytic module 11 is connected with the first row water hole of hydrogen collecting apparatus 21;
5. utilize conduit 51 to be connected with the venthole of hydrogen collecting apparatus 21 with oxygen gatherer 22 respectively by two vent valves 52, connected as shown in figure 15;
6., respectively to injecting distilled water in hydrogen collecting apparatus 21 and oxygen gatherer 22 to " water line " position, by pressing vent valve 52 distilled water injected the below (now distilled water fills gas collector inside) of gatherer;
7. power supply adaptor is connected with blower fan 92, regulator potentiometer, increases wind speed, observe in hydrogen collecting apparatus 21 and oxygen gatherer 22 and whether have gas to generate;
8. arrange experiment equipment.
The beneficial effects of the utility model are:
By combining various relevant with the Hydrogen Energy experiment equipment provided, the experimental modelling about Hydrogen Energy can be realized, thus solve the problem lacked about the experiment device for teaching of Hydrogen Energy.
Below embodiment has been described in detail the utility model by reference to the accompanying drawings, and those skilled in the art can make many variations example to the utility model according to the above description.Thus, some details in embodiment should not formed restriction of the present utility model, the utility model by the scope that defines using appended claims as protection domain.
Claims (8)
1. a Hydrogen Energy experimental provision, is characterized in that, comprising:
Electrolytic module, is provided with electrolysis power jack, electrolysis hydrogen venthole, electrolysis hydrogen inlet opening, electrolytic oxygen venthole and electrolytic oxygen inlet opening;
Hydrogen collecting apparatus, be provided be communicated with described electrolysis hydrogen venthole hydrogen gas hole, hydrogen exhaust hole, hydrogen volume scale, the first distilled water ordinary water level and the first row water hole that is communicated with described electrolysis hydrogen inlet opening;
Oxygen gatherer, be provided be communicated with described electrolysis hydrogen venthole hydrogen gas hole, oxygen vent port, oxygen volume markings, after-fractionating water ordinary water level and the second row water hole that is communicated with described electrolytic oxygen inlet opening;
Pressure regulator, the electrolysis be provided with for being electrically connected described electrolysis power jack connects jack, for changing adjusting pressuring knob and the voltage controller power source jack of output voltage; And
Timer.
2. Hydrogen Energy experimental provision according to claim 1, is characterized in that, also comprise: be connected to the reometer between described electrolytic module and described pressure regulator.
3. Hydrogen Energy experimental provision according to claim 2, is characterized in that, also comprise: the voltage table in parallel with described electrolytic module.
4. Hydrogen Energy experimental provision according to claim 1, is characterized in that, also comprise:
Electricity generation module, is provided with power generating source jack, the generating oxygen air admission hole be communicated with described oxygen vent port, the oxygen vent port that generates electricity, the generating hydrogen gas hole be communicated with described hydrogen exhaust hole and the hydrogen exhaust hole that generates electricity;
For being electrically connected the first load of described electricity generation module, comprise motor, for being electrically connected the motor socket of described motor, bulb and the light bulb socket for being electrically connected described bulb.
5. Hydrogen Energy experimental provision according to claim 1, is characterized in that, also comprise:
Electricity generation module, is provided with power generating source jack, the generating oxygen air admission hole be communicated with described oxygen vent port, the oxygen vent port that generates electricity, the generating hydrogen gas hole be communicated with described hydrogen exhaust hole and the hydrogen exhaust hole that generates electricity;
Second load, comprise with electric loading, to connect for the generating being electrically connected described power generating source jack jack, for measuring voltage value voltage socket, for measure current value current sockets and for regulating the knob of the resistance value of described electric loading;
For being electrically connected the voltage table of described voltage socket; And
For being electrically connected described current sockets reometer.
6. the Hydrogen Energy experimental provision according to claim 4 or 5, it is characterized in that, also comprising the first battery base for placing described electrolytic module, for placing the second battery base of described electricity generation module and the gas collector base for placing described hydrogen collecting apparatus and described oxygen gatherer.
7. Hydrogen Energy experimental provision according to claim 1, is characterized in that, described pressure regulator is also equipped with the power supply adaptor for being electrically connected described voltage controller power source jack.
8. Hydrogen Energy experimental provision according to claim 1, is characterized in that, also comprises the vent valve for connecting described hydrogen exhaust hole and described oxygen vent port.
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| CN201520190020.XU CN204596293U (en) | 2015-04-01 | 2015-04-01 | Hydrogen Energy experimental provision |
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| CN201520190020.XU CN204596293U (en) | 2015-04-01 | 2015-04-01 | Hydrogen Energy experimental provision |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN106157769A (en) * | 2015-04-01 | 2016-11-23 | 普教装备产业股份有限公司 | Hydrogen Energy experimental provision |
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| Publication number | Priority date | Publication date | Assignee | Title |
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| CN106157769A (en) * | 2015-04-01 | 2016-11-23 | 普教装备产业股份有限公司 | Hydrogen Energy experimental provision |
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Effective date of registration: 20190125 Address after: Nine Blocks, 38 Dujiabang Road, Sijing Town, Songjiang District, Shanghai, 20101 Patentee after: Shanghai East Teaching Co., Ltd. Address before: No. 88 Fangsi Road, Sijing Town, Songjiang District, Shanghai, 20101 Patentee before: PUJIAO EQUIPMENT INDUSTRY CO., LTD. |
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