CN212669209U

CN212669209U - Module for hydrogen-fuel cell for hydrogen production device

Info

Publication number: CN212669209U
Application number: CN202022070062.3U
Authority: CN
Inventors: 余守斌
Original assignee: Fujian Haixia Liangan Environment Engineering Co ltd
Current assignee: Fujian Haixia Liangan Environment Engineering Co ltd
Priority date: 2019-11-25
Filing date: 2020-09-18
Publication date: 2021-03-09
Anticipated expiration: 2030-09-18
Also published as: CN112209336A

Abstract

The utility model discloses a belong to new energy device technical field, specifically be an use module of hydrogen apparatus for producing supplies hydrogen fuel cell, which comprises a housing, the inner box, power supply unit, the aspiration pump, mounting panel and heelpiece, this kind of use module of hydrogen apparatus for producing supplies hydrogen fuel cell, usable main electrode and auxiliary electrode are connected to power supply unit, power supply unit exports high frequency power and makes and have the potential difference and produce plasma between main electrode and the auxiliary electrode, plasma forms the plasma post under the separation guide of aspiration pump, the plasma post helps hydrogen-containing substance to decompose out hydrogen composition, in order to provide the hydrogen source, safety ring protects, and utilize the aspiration pump to collect the back transfer to among the hydrogen bottle, and in the direct transmission to fuel cell after the cooperation purification equipment handles, and the mounting panel intussuseption is filled with the heelpiece, the heelpiece utilizes body frame and subframe connection crossbearer, the cooperation spring can effectively kick-back, the built-in buffer board and the interior pad of setting at the heelpiece further increase the buffer capacity, and it is effectual to stabilize.

Description

Module for hydrogen-fuel cell for hydrogen production device

Technical Field

The utility model relates to a new forms of energy device technical field specifically is a module of using hydrogen apparatus for producing to supply hydrogen fuel cell.

Background

The hydrogen station is a gas station for supplying hydrogen gas to the fuel cell vehicle, and can supply hydrogen gas to the fuel cell vehicle as an infrastructure for supplying hydrogen gas to the fuel cell vehicle.

The most important component hydrogen is generally hydrogen in a simple substance form, which is colorless, tasteless, odorless and extremely combustible gas consisting of diatomic molecules, and hydrogen is the lightest gas and is a clean renewable energy source with high energy density.

At present, the in-process of current hydrogen apparatus for producing confession hydrogen fuel cell needs cooperation transmission and storage device to shift the storage back to hydrogen, and the hydrogenation rifle that deuterogamies carries out the air entrainment work, and the flexibility is relatively poor, and is great to the dependence of outside air entrainment device, uses the restriction, and in combining with the device, receives the motion influence can produce and rock the condition, influences the equipment accessories precision, dangerous improvement.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an use module of hydrogen apparatus for producing confession hydrogen fuel cell to solve the in-process that the current hydrogen apparatus for producing that proposes in the above-mentioned background uses hydrogen fuel cell, need cooperate transmission and storage device to come to shift the storage back to hydrogen, it carries out the air entrainment work to cooperate the hydrogenation rifle again, the flexibility is relatively poor, it is great to the dependence of outside air entrainment device, the use is limited, and in combining with the device, the condition of rocking can produce by the motion influence, influence equipment accessory precision, the problem of dangerous improvement.

In order to achieve the above object, the utility model provides a following technical scheme: a module for a hydrogen-fuel cell for a hydrogen production device comprises a shell, an inner box, a power supply device, an air suction pump, a mounting plate and a bottom pad, wherein the inner cavity bottom of the shell is fixedly connected with the inner box through bolts, the front side wall of the shell is fixedly connected with the power supply device through screws, the top of the inner cavity of the shell is fixedly connected with a hydrogen bottle through screws, the bottom of the hydrogen bottle is connected with the air suction pump through a flange, the right side wall of the shell is fixedly connected with the mounting plate through screws, the bottom pad is embedded in the inner side of the right side wall of the mounting plate, the left side wall of the shell is provided with an air alternating-flow hole, an inner groove is reserved in the inner cavity of the inner box, the inner cavity bottom of the inner box is fixedly connected with an oscillator through screws, the electrical output end of the power supply device is electrically connected with a main electrode and an auxiliary electrode through wires, the alternating current frequency is between 2kHz and 20kHz, the voltage is between 4000V and 14000V, potential difference is formed between the main electrode and the auxiliary electrode to generate plasma, the plasma forms a plasma column by means of air flow generated by the air suction pump and is stored between the main electrode and the auxiliary electrode, the top of the shell is fixedly connected with purification equipment through bolts, the top of the purification equipment is connected with a transfer pipe through a flange, the output end of the transfer pipe is connected with a fuel cell through a flange, the right side wall of the mounting plate is spliced with a screw rod, the bottom of the inner cavity of the bottom pad is bonded with an inner pad, the bottom of the bottom pad is spliced with a pin shaft, the bottom of the pin shaft is spliced with a main frame, the bottom of the main frame is movably connected with a transverse frame through a flange, and the bottom of the transverse frame is movably connected with the auxiliary frame through a shaft rod, the bottom of the auxiliary frame is movably connected with a backing plate through a pin shaft.

Preferably, the bottom of the bottom pad is provided with a groove, and the number of the bottom pads is two.

Preferably, a buffer plate is bonded to the bottom of the inner cavity of the bottom pad, and the bottom of the buffer plate is bonded to the top of the inner pad.

Preferably, the left side wall of the backing plate is fixedly connected with the right side wall of the inner cavity of the mounting plate.

Preferably, the top and bottom of the buffer plate are embossed with a honeycomb structure.

Preferably, the bottom of the bottom pad is welded with a spring, and the bottom of the spring is welded with the top of the backing plate.

Compared with the prior art, the beneficial effects of the utility model are that: this kind of use module of hydrogen apparatus for producing supplies hydrogen fuel cell, through the combination application of accessory, usable main electrode and auxiliary electrode are connected to power supply unit, power supply unit exports high frequency power and makes to have the potential difference between main electrode and the auxiliary electrode and produce plasma, plasma forms the plasma post under the separation guide of aspiration pump, the hydrogen composition is decomposed out to the plasma post help contains hydrogen material, in order to provide the hydrogen source, safety ring protects, and utilize the aspiration pump to collect the back and shift to during the hydrogen bottle, and cooperate during purification equipment handles the back direct transfer to fuel cell, and the inside packing of mounting panel has the heelpiece, the heelpiece utilizes body frame and subframe to connect the crossbearer, cooperation spring can effectively kick-back, set up buffer board and inner pad in the built-in of heelpiece, further increase the buffer capacity, it is stable effectual.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the bottom mat of the present invention;

FIG. 3 is a schematic view of the structure of the bottom pad of the present invention;

fig. 4 is a block diagram illustrating the process of the present invention.

In the figure: 100 outer shell, 200 inner box, 210 oscillator, 220 inner tank, 300 power supply device, 310 main electrode, 320 auxiliary electrode, 330 plasma column, 400 air pump, 410 hydrogen bottle, 420 purification equipment, 430 transfer tube, 440 fuel cell, 500 mounting plate, 510 screw, 600 bottom pad, 610 groove, 620 pin shaft, 630 buffer plate, 640 inner pad, 650 main frame, 660 cross frame, 670 auxiliary frame, 680 base plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a module for hydrogen fuel cell using hydrogen production device, which is convenient for increasing the integrity and reducing the external dependence on the basis of utilizing new energy through the combined application of accessories, and has high safety factor, please refer to fig. 1-4, comprising a shell 100, an inner box 200, a power supply device 300, an air pump 400, a mounting plate 500 and a base pad 600;

referring to fig. 1 again, the bottom of the inner box 200 and the bottom of the inner cavity of the outer shell 100, specifically, the bottom of the inner cavity of the outer shell 100 is fixedly connected to the inner box 200 through bolts, an inner groove 220 is reserved in the inner cavity of the inner box 200, and the bottom of the inner cavity of the inner box 200 is fixedly connected to the oscillator 210 through screws;

referring to fig. 1 again, the bottom of the power supply device 300 is fixedly connected to the top of the inner tank 220, specifically, the front side wall of the housing 100 is fixedly connected to the power supply device 300 through bolts, the electrical output end of the power supply device 300 is electrically connected to the main electrode 310 and the auxiliary electrode 320 through wires, the power supply device 300 provides alternating current to the main electrode 310 and the auxiliary electrode 320, the frequency of the alternating current is between 2kHz and 20kHz, the voltage is between 4000V and 14000V, a potential difference exists between the main electrode 310 and the auxiliary electrode 320 to generate plasma, and the plasma forms a plasma column 330 between the main electrode 310 and the auxiliary electrode 320 by means of the airflow generated by the air pump 400;

referring to fig. 1 again, the bottom of the air pump 400 is fixedly connected to the inner cavity of the housing 100, specifically, the left sidewall of the housing 100 is provided with an air cross-flow hole, the top of the inner cavity of the housing 100 is fixedly connected to a hydrogen bottle 410 through a screw, the bottom of the hydrogen bottle 410 is connected to the air pump 400 through a flange, the top of the housing 100 is fixedly connected to a purification device 420 through a bolt, the top of the purification device 420 is connected to a transfer pipe 430 through a flange, the output end of the transfer pipe 430 is connected to a fuel cell 440 through a flange, and the process is as follows: an air exchange hole is reserved on the left side wall of the housing 100 to achieve the effect of air circulation, so that a small amount of air can be stored inside the housing 100, a hydrogen-containing substance is added into the inner groove 220 containing the oscillator 210, the hydrogen-containing substance is a group consisting of gasoline, diesel oil, biodiesel, alcohol and ammonia, the oscillator 510 is in contact with the hydrogen-containing substance, the oscillator 510 can use a piezoelectric element generating high-frequency oscillation, so that the liquid hydrogen-containing substance forms a plurality of fine liquid particles to be drifted in the housing 100 or enter the housing 100 along with the airflow, the main electrode 310 and the auxiliary electrode 320 are connected to the power supply device 300, the power supply device 130 provides alternating current to the main electrode 310 and the auxiliary electrode 320, the frequency of the alternating current is between 2kHz and 20kHz, the voltage is between 4000V and 14000V, the air and the hydrogen-containing substance are mixed between the main electrode 310 and the auxiliary electrode 320, and plasma chemical reaction occurs under the effect of a plasma column 330 between the main electrode 310 and the auxiliary electrode 320, the reaction process is that the plasma column 330 has many charged particles with high energy free state, when the hydrogen-containing substance enters the shell 100 from the inner groove 220, the charged particles impact the hydrogen-carbon bond to be destroyed, thereby generating hydrogen component, the hydrogen component is decomposed out from the hydrogen-containing substance and is delivered to the hydrogen bottle 410 through the air pump 400, and is transferred to the fuel cell 440 through the transfer pipe 430 after the purification equipment 420, wherein the purification equipment 420 takes the electrolytic hydrogen as the raw material, and is subject to catalytic deoxidization, absorption secondary drying, and then the filter is used to remove the impurity oxygen, water vapor and dust in the hydrogen to obtain high purity hydrogen, the purity of the high purity hydrogen can reach more than 99.9995%, which is not repeated in the prior art;

referring to fig. 1 again, the left side wall of the mounting plate 500 is fixedly connected with the right side wall of the housing 100, specifically, the right side wall of the housing 100 is fixedly connected with the mounting plate 500 through screws, and the right side wall of the mounting plate 500 is inserted with a screw 510;

referring to fig. 1-3 again, the left sidewall of the bottom pad 600 is fixedly connected with the right sidewall of the mounting plate 500, specifically, the bottom pad 600 is embedded inside the right sidewall of the mounting plate 500, the inner pad 640 is bonded to the bottom of the inner cavity of the bottom pad 600, the pin shaft 620 is inserted into the bottom of the bottom pad 600, the main frame 650 is inserted into the bottom of the pin shaft 620, the bottom of the main frame 650 is movably connected with the cross frame 660 through a shaft rod, the bottom of the cross frame 660 is movably connected with the sub frame 670 through a shaft rod, and the bottom of the sub frame 670 is movably connected with the backing plate 680 through the pin shaft 620;

when the device is used specifically, firstly the mounting plate 500 is assembled on the right side wall of the housing 100, and two bottom cushions 600 with the same structure are arranged on the inner side of the mounting plate 500, the inside of the bottom cushion 600 contains the buffer plate 630 and the inner cushion 640, which can effectively increase the buffer capacity, and the main frame 650, the cross frame 660 and the sub frame 670 which are movably assembled together are matched with the cushion plate 680 to form a buffer bracket, and the two side springs are matched to effectively ensure the buffer effect after the assembly, secondly the main electrode 310 and the sub electrode 320 are connected to the power supply device 330, the power supply device 330 outputs a high-frequency power supply to enable a potential difference between the main electrode 310 and the sub electrode 320 to generate a plasma, so that the hydrogen-containing substance is decomposed into hydrogen components, and the hydrogen components are transferred to the inside of the purification device 420 after being collected by the air pump 400, the hydrogen outlet of the purification device 420 is connected with the fuel cell, the purification device 420 uses electrolytic hydrogen as raw material, and removes impurity oxygen, water vapor and dust in the hydrogen through catalytic deoxygenation cooling and adsorption secondary drying, and then the high-purity hydrogen is obtained through a filter, and the purity of the high-purity hydrogen can reach more than 99.9995%.

Referring to fig. 2-3 again, in order to increase the stabilizing effect, specifically, the bottom of the bottom pad 600 is provided with two grooves 610, the number of the bottom pads 600 is two, the bottom of the inner cavity of the bottom pad 600 is bonded with the buffer board 630, the bottom of the buffer board 630 is bonded with the top of the inner pad 640, and the left side wall of the cushion board 680 is fixedly connected with the right side wall of the inner cavity of the mounting plate 500.

Referring to fig. 2 to 3 again, in order to increase the strength and the pressure relief capability of the buffer plate 630 and further improve the buffering effect, specifically, the top and the bottom of the buffer plate 630 are embossed with a honeycomb structure, the bottom of the bottom pad 600 is welded with a spring, and the bottom of the spring is welded with the top of the backing plate 680.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of such combinations is not exhaustive in the present specification only for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims

1. A module for a hydrogen-fuel cell using a hydrogen production apparatus, comprising: comprises a shell (100), an inner box (200), a power supply device (300), an air suction pump (400), a mounting plate (500) and a bottom pad (600), wherein the inner cavity bottom of the shell (100) is fixedly connected with the inner box (200) through a bolt, the front side wall of the shell (100) is fixedly connected with the power supply device (300) through a screw, the inner cavity top of the shell (100) is fixedly connected with a hydrogen bottle (410) through a screw, the bottom of the hydrogen bottle (410) is connected with the air suction pump (400) through a flange, the right side wall of the shell (100) is fixedly connected with the mounting plate (500) through a screw, the bottom pad (600) is embedded in the inner side of the right side wall of the mounting plate (500), an air cross-flow hole is formed in the left side wall of the shell (100), an inner groove (220) is reserved in the inner cavity of the inner box (200), an oscillator (210) is fixedly connected with, the electrical output end of the power supply device (300) is electrically connected with a main electrode (310) and an auxiliary electrode (320) through a lead, the power supply device (300) provides alternating current to the main electrode (310) and the auxiliary electrode (320), the frequency of the alternating current is between 2kHz and 20kHz, the voltage is between 4000V and 14000V, the main electrode (310) and the auxiliary electrode (320) have potential difference to generate plasma, the plasma forms a plasma column (330) through the airflow generated by the air suction pump (400), and is arranged between the main electrode (310) and the auxiliary electrode (320), the top of the casing (100) is fixedly connected with a purifying device (420) through a bolt, the top of the purifying device (420) is connected with a transfer pipe (430) through a flange, the output end of the transfer pipe (430) is connected with a fuel cell (440) through a flange, the right side wall of mounting panel (500) is pegged graft and is had screw rod (510), the inner chamber bottom of heelpiece (600) bonds and has interior pad (640), the bottom of heelpiece (600) is pegged graft and is had round pin axle (620), the bottom of round pin axle (620) is pegged graft and is had body frame (650), the bottom of body frame (650) has crossbearer (660) through axostylus axostyle swing joint, the bottom of crossbearer (660) has subframe (670) through axostylus axostyle swing joint, the bottom of subframe (670) has backing plate (680) through round pin axle (620) swing joint.

2. A module for a hydrogen-fired battery using a hydrogen production apparatus according to claim 1, wherein: the bottom of the bottom pad (600) is provided with a groove (610), and the number of the bottom pad (600) is two.

3. A module for a hydrogen-fired battery using a hydrogen production apparatus according to claim 1, wherein: the bottom of the inner cavity of the bottom pad (600) is bonded with a buffer plate (630), and the bottom of the buffer plate (630) is bonded with the top of the inner pad (640).

4. A module for a hydrogen-fired battery using a hydrogen production apparatus according to claim 1, wherein: the left side wall of the backing plate (680) is fixedly connected with the right side wall of the inner cavity of the mounting plate (500).

5. A module for a hydrogen-fired battery using a hydrogen production apparatus according to claim 3, wherein: the top and bottom of the buffer plate (630) are embossed with a honeycomb structure.

6. A module for a hydrogen-fired battery using a hydrogen production apparatus according to claim 1, wherein: the bottom of the bottom pad (600) is welded with a spring, and the bottom of the spring is welded with the top of the backing plate (680).