CN215757653U - Integrated intelligent water electrolysis oxyhydrogen generator system station - Google Patents

Abstract

The utility model discloses an integrated intelligent water electrolysis oxyhydrogen generator system station, which comprises: the device comprises a cabinet body, a camera and a hydrogen and oxygen sensor, wherein a plurality of side doors are arranged on two sides of the cabinet body; the water electrolysis oxyhydrogen generator modules are respectively arranged corresponding to the positions of the corresponding side doors, each water electrolysis oxyhydrogen generator module is provided with a temperature sensor, a pressure sensor and an electromagnetic valve, the temperature sensor is arranged on the electrolytic bath, and the pressure sensor and the electromagnetic valve are arranged on an exhaust pipe on the electrolytic bath; the water supply storage tank is arranged at the top end of the cabinet body, the water outlets of the water supply storage tank are respectively communicated with the plurality of electrolytic tanks through pipelines, and the pipelines are provided with corresponding switch valves; the power supply main management cabinet is electrically connected with the electrolysis power supply boxes on the water electrolysis oxyhydrogen generator modules; and a remote management platform. The system station is simpler and more flexible, occupies a small area, has low cost and is suitable for wide popularization.

Description

Integrated intelligent water electrolysis oxyhydrogen generator system station

Technical Field

The utility model relates to the technical field of oxyhydrogen generators, in particular to an integrated intelligent water electrolysis oxyhydrogen generator system station.

Background

At present, process equipment for producing hydrogen and oxygen mixed gas by small and medium-sized water electrolysis hydrogen production or water electrolysis hydrogen production is supplied to the market in a single set mode, and the single gas production is mostly not higher than 20000m³H, simultaneously supplying air to a plurality of sleeves or requiring air supply amount more than 20000m³Under the use environment of more than/h, a plurality of small and medium-sized water electrolysis devices need to be concentrated in an independent space range so as to meet the use requirements of a large number of air supply points or a large air consumption requirement. For the convenience of management requirements of operation, maintenance, safety and the like of equipment, the water electrolysis oxyhydrogen generation device (or equipment) needs an independent working space for convenient management, for example, in steel enterprises, a hydrogen and oxygen generator workstation is generally established by selecting an area in advance and utilizing a brick-concrete or steel frame structure, and a plurality of sets of hydrogen and oxygen generators are arranged in the workstation to achieve the purpose of centralized management. The scheme for building the hydrogen-oxygen generation station is very common in the market at present, has strict requirements on steel mills, needs to meet multiple design specification requirements of buildings, water heating, ventilation, industrial gas safety and the like at the same time, and is not beneficial to reducing the cost because a large amount of money and manpower are invested for building the hydrogen-oxygen station each time; moreover, steel mills have different conditions and are greatly restricted by the conditions of site, cost, design safety and the like, so that the application of the oxyhydrogen generator is often hindered by the restrictions.

In addition, each oxyhydrogen generator in the workstation is an integral machine used at present, namely each power supply system and each electrolytic cell use an integral frame and generator shell, and the problem of the scheme is that: space utilization is low, and every equipment uses the waste of independent frame and generator shell to cause the material, and is with high costs.

Therefore, in order to solve the above problems encountered when a water electrolysis oxyhydrogen generator is adopted in a steel mill, how to provide an integrated intelligent water electrolysis oxyhydrogen generator system station which is simpler, more flexible, has a small floor area and is low in cost is a problem that needs to be solved by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of the above, the utility model provides an integrated intelligent water electrolysis oxyhydrogen generator system station which is simpler, more flexible, small in occupied area and low in cost.

In order to achieve the purpose, the utility model adopts the following technical scheme:

integrative integrated form intelligence water electrolysis oxyhydrogen generator system station includes:

the intelligent cabinet comprises a cabinet body, a plurality of side doors are arranged on two sides of the cabinet body, a camera is arranged on the top wall in the cabinet body, and a hydrogen and oxygen sensor is arranged on one inner side wall of the cabinet body;

the water electrolysis hydrogen and oxygen generator modules are distributed in the cabinet body along the length direction of the cabinet body and are respectively arranged corresponding to the positions of the corresponding side doors, each water electrolysis hydrogen and oxygen generator module is provided with a temperature sensor for detecting the temperature of the electrolytic cell, a pressure sensor for detecting the pressure of produced air and an electromagnetic valve for closing the produced air, the temperature sensor is arranged on the electrolytic cell, and the pressure sensor and the electromagnetic valve are arranged on an exhaust pipe on the electrolytic cell;

the water supply storage tank is arranged at the top end of the cabinet body, the water outlet of the water supply storage tank is respectively communicated with the plurality of electrolytic cells through pipelines, and the pipelines are provided with corresponding switch valves;

the power supply main management cabinet is arranged on one side in the cabinet body and is respectively and electrically connected with the electrolytic power boxes on the water electrolysis oxyhydrogen generator modules;

the remote management platform, the remote management platform all with the camera the oxyhydrogen gas sensor temperature sensor pressure sensor solenoid valve the ooff valve power supply total management cabinet radio connection.

According to the technical scheme, compared with the prior art, the integrated intelligent water electrolysis oxyhydrogen generator system station adopts an integrated cabinet body frame to construct a whole oxyhydrogen generation room with the station as a unit, so that the brick mixing and steel frame structure in the traditional process is omitted, the packaging cost of a plurality of single devices is saved, the use is more convenient and flexible, the installation is convenient and fast, the occupied area is small, the oxyhydrogen generation station is not required to be built with high investment, and the early-stage investment cost is reduced. In addition, the use condition of field equipment can be observed in real time through the camera by the remote management platform, the on-site oxyhydrogen gas leakage condition, the produced oxyhydrogen gas pressure condition and the temperature condition in the working of the electrolytic cell can be monitored, and when a problem occurs, the electromagnetic valve, the switch valve and the power supply main management cabinet can be remotely controlled by the remote management platform to stop working, so that the gas production of the system station is stopped, and the use safety of the system station is improved. Therefore, the system station adopts intelligent management, so that the field management of personnel can be reduced, the working intensity of the personnel is reduced, and the safety of the personnel is improved.

The water treatment device is characterized by further comprising a water treatment device arranged in the cabinet body, a water inlet of the water treatment device is connected with an external water source through a first water delivery pipe, and a water outlet of the water treatment device is connected with a water inlet of the water supply storage tank through a second water delivery pipe.

Adopt above-mentioned technical scheme to produce beneficial effect is that water treatment facilities can convert on-the-spot water source to be exclusively used in the pure water or the distilled water under the electrolysis condition and store in supplying water storage tank, provides the water source for equipment.

Furthermore, the electrolytic cell cabinet also comprises a plurality of placing frames arranged in the cabinet body, the electrolytic cell is placed below the placing frames, and the electrolytic power supply box is placed at the top ends of the placing frames.

The water electrolysis oxyhydrogen generator module has the beneficial effects that the space is fully utilized, the occupied space of the water electrolysis oxyhydrogen generator module in the cabinet body is reduced, and the occupied area of the whole system station is greatly reduced.

Further, it is a plurality of the rack is the multirow and arranges, just lie in adjacent two rows on the internal diapire of cabinet body lay the edge between the rack longitudinal rail that cabinet body length direction arranged, lie in on the internal diapire of cabinet body lay the edge below the rack the horizontal track that cabinet body width direction arranged, the electrolysis trough is placed on the horizontal track.

Furthermore, the bottom end of the electrolytic cell is provided with a moving wheel which is in rolling contact with the transverse rail.

The beneficial effect who adopts above-mentioned technical scheme to produce is, opens the side door, can push out the electrolysis trough along horizontal track propulsion, and the electrolysis power supply case can move along longitudinal rail, moves to the back in place, moves to the rack again, is convenient for the maintenance and the change of electrolysis trough and electrolysis power supply case.

Furthermore, the position of the transverse track far away from the side door is provided with a stopping upright post for stopping the moving wheel.

Adopt above-mentioned technical scheme to produce beneficial effect is, when installing the electrolysis trough, impel the electrolysis trough along horizontal track, can with backstop stand butt when removing the wheel, can prevent that the electrolysis trough from pushing out transverse guide.

Further, install on the side door with remote management platform radio connection's cooling blower.

Adopt above-mentioned technical scheme to produce the beneficial effect be, adopt and control the configuration form, form the stable ventilation heat dissipation of fixed wind channel in the box.

Furthermore, the exhaust pipe extends out of the cabinet body to be connected with an external anti-backfire safety header tank.

Adopt above-mentioned technical scheme to produce beneficial effect be, can effectively prevent that flame from tempering and taking place danger.

Furthermore, a front door is arranged on the front side of the cabinet body.

Adopt the beneficial effect that above-mentioned technical scheme produced to be convenient for cabinet body internal apparatus's management.

Further, the cabinet body is formed by welding metal plates.

The cabinet body has the advantages of low cost and simple manufacture, and can be processed according to actual needs or formed by splicing a plurality of cabinet bodies.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an integrated intelligent water electrolysis oxyhydrogen generator system station provided by the utility model.

Fig. 2 is a schematic diagram of the internal structure of fig. 1 from a first perspective.

Fig. 3 is an enlarged schematic view of the structure of the part a in fig. 2.

Fig. 4 is a schematic diagram of the internal structure of fig. 1 from a second perspective.

Fig. 5 is an enlarged schematic view of the structure of the part B in fig. 4.

FIG. 6 is a schematic structural diagram of the connection between the air outlet pipe of a single electrolytic cell and the anti-backfire safety header tank.

FIG. 7 is a schematic view showing the structure of the connection of the water treatment apparatus, the water supply storage tank and a plurality of electrolytic cells.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the embodiment of the utility model discloses an integrated intelligent water electrolysis oxyhydrogen generator system station, comprising:

the intelligent cabinet comprises a cabinet body 1, wherein a plurality of side doors 2 are arranged on two sides of the cabinet body 1, a camera 3 is arranged on the inner top wall of the cabinet body 1, and a hydrogen-oxygen sensor 4 is arranged on one inner side wall of the cabinet body 1;

the water electrolysis oxyhydrogen generator modules 5 are arranged in the cabinet body 1 along the length direction of the cabinet body 1 and are respectively arranged corresponding to the positions of the corresponding side doors 2, each water electrolysis oxyhydrogen generator module 5 is provided with a temperature sensor 6 for detecting the temperature of the electrolytic bath 51, a pressure sensor 7 for detecting the pressure of produced air and an electromagnetic valve 8 for closing the produced air, the temperature sensor 6 is arranged on the electrolytic bath 51, and the pressure sensor 7 and the electromagnetic valve 8 are both arranged on an exhaust pipe 511 on the electrolytic bath 51;

the water supply and storage tank 9 is arranged at the top end of the cabinet body 1, the water outlets of the water supply and storage tank 9 are respectively communicated with the plurality of electrolytic cells 51 through pipelines 10, and the pipelines 10 are provided with corresponding switch valves 11;

the power supply main management cabinet 12 is arranged on one side inside the cabinet body 1, and the power supply main management cabinet 12 is respectively and electrically connected with the electrolytic power boxes 52 on the water electrolysis oxyhydrogen generator modules 5;

the remote management platform 13 and the remote management platform 13 are all in wireless connection with the camera 3, the oxyhydrogen gas sensor 4, the temperature sensor 6, the pressure sensor 7, the electromagnetic valve 8, the switch valve 11 and the power supply main management cabinet 12.

The integrated intelligent water electrolysis oxyhydrogen generator system station further comprises a water treatment device 14 arranged in the cabinet body 1, a water inlet of the water treatment device 14 is connected with an external water source through a first water delivery pipe 15, and a water outlet of the water treatment device 14 is connected with a water inlet of the water supply storage tank 9 through a second water delivery pipe 16.

The integrated intelligent water electrolysis oxyhydrogen generator system station further comprises a plurality of placing frames 17 arranged in the cabinet body 1, an electrolytic tank 51 is placed below the placing frames 17, and an electrolysis power box 52 is placed at the top end of the placing frames 17.

The plurality of placing frames 17 are arranged in a plurality of rows, longitudinal rails 18 arranged along the length direction of the cabinet body 1 are laid between the placing frames 17 positioned in two adjacent rows on the inner bottom wall of the cabinet body 1, transverse rails 19 arranged along the width direction of the cabinet body 1 are laid below the placing frames 17 on the inner bottom wall of the cabinet body 1, and the electrolytic bath 51 is placed on the transverse rails 19.

The bottom end of the electrolytic bath 51 is provided with a moving wheel 20, and the moving wheel 20 is in rolling contact with the transverse rail 19.

The transverse rail 19 is provided, at a position remote from the side door 2, with a stop upright 21 for stopping the moving wheel 20.

And a heat radiation fan 22 which is in wireless connection with the remote management platform 13 is arranged on the side door 2.

The exhaust pipe 511 extends out of the cabinet body 1 and is connected with an external anti-backfire safety collecting cabinet 23.

The front door 24 is arranged at the front side of the cabinet body 1.

The cabinet body 1 is formed by welding metal plates.

According to the integrated intelligent water electrolysis oxyhydrogen generator system station, an integrated cabinet body framework is adopted to construct a whole station-based oxyhydrogen generation room, so that the traditional brick mixing and steel frame structure is omitted, the packaging cost of a plurality of single devices is saved, the use is more convenient and flexible, the installation is convenient and fast, the occupied area is small, the oxyhydrogen generation station is not constructed with too high investment, and the early investment cost is reduced. In addition, the use condition of field equipment can be observed in real time through the camera by the remote management platform, the leakage condition of oxyhydrogen and oxygen on the site, the pressure condition of produced oxyhydrogen and oxygen and the temperature condition of the electrolytic cell during working can be monitored, and when a problem occurs, the electromagnetic valve, the switch valve and the power supply main management cabinet can be remotely controlled to stop working by the remote management platform (a one-key start-stop button can be arranged), so that the gas production of the system station is stopped, and the use safety of the system station is improved. Therefore, the system station adopts intelligent management, so that the field personnel allocation and field management can be reduced, the working intensity of personnel is reduced, and the safety of the personnel is improved.

The utility model has the following advantages:

the utility model adopts an integrated box type frame to construct a whole hydrogen and oxygen generation room taking a station as a unit, and the whole transportation is adopted during transportation, thereby saving the packaging cost of a plurality of single devices.

The station body saves brick concrete and steel frame structures in the original scheme, an integrated box-type frame which is more convenient and flexible to use is used, the hydrogen and oxygen generation station is built without high investment, and the early-stage investment cost is reduced;

the integrated oxyhydrogen room double-side doors can be opened, and the internal electrolytic tank and the internal electrolytic power supply box can be quickly maintained or replaced through the internal longitudinal and transverse sliding rails, so that the operation is very simple and convenient, and manpower and material resources are saved;

the integrated hydrogen-oxygen station occupies smaller area and has smaller requirement on the site in actual use;

the integrated hydrogen-oxygen station can be moved as a whole to be placed in place, or the position can be changed at any time, the hydrogen-oxygen station is flexible to place and convenient to install.

Sixthly, the water electrolysis oxyhydrogen generator modules adopt independent electrolytic tanks and electrolytic power boxes, and no shell is required to be wrapped, so that the material consumption is reduced, and the manufacturing cost of a system station can be further reduced.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. Integrative integrated form intelligence water electrolysis oxyhydrogen generator system station, its characterized in that includes:

the intelligent cabinet comprises a cabinet body (1), wherein a plurality of side doors (2) are arranged on two sides of the cabinet body (1), a camera (3) is arranged on the inner top wall of the cabinet body (1), and a hydrogen-oxygen sensor (4) is arranged on one inner side wall of the cabinet body (1);

the water electrolysis hydrogen and oxygen generator modules (5) are distributed in the cabinet body (1) along the length direction of the cabinet body (1) and are respectively arranged corresponding to the positions of the corresponding side doors (2), each water electrolysis hydrogen and oxygen generator module (5) is provided with a temperature sensor (6) for detecting the temperature of the electrolytic cell (51), a pressure sensor (7) for detecting the pressure of produced air and an electromagnetic valve (8) for closing the produced air, the temperature sensor (6) is arranged on the electrolytic cell (51), and the pressure sensor (7) and the electromagnetic valve (8) are arranged on an exhaust pipe (511) on the electrolytic cell (51);

the water supply and storage tank (9) is arranged at the top end of the cabinet body (1), the water outlets of the water supply and storage tank (9) are respectively communicated with the plurality of electrolytic cells (51) through pipelines (10), and the pipelines (10) are provided with corresponding switch valves (11);

the power supply main management cabinet (12), the power supply main management cabinet (12) is arranged on one side in the cabinet body (1) and is respectively and electrically connected with the electrolytic power boxes (52) on the water electrolysis oxyhydrogen generator modules (5);

remote management platform (13), remote management platform (13) all with camera (3), oxyhydrogen gas sensor (4), temperature sensor (6), pressure sensor (7) solenoid valve (8) ooff valve (11) power supply total management cabinet (12) radio connection.

2. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 1, further comprising a water treatment device (14) disposed in the cabinet (1), wherein a water inlet of the water treatment device (14) is connected with an external water source through a first water pipe (15), and a water outlet of the water treatment device (14) is connected with a water inlet of the water supply storage tank (9) through a second water pipe (16).

3. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 1, further comprising a plurality of racks (17) arranged in the cabinet body (1), wherein the electrolytic tank (51) is placed under the racks (17), and the electrolysis power box (52) is placed at the top end of the racks (17).

4. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 3, wherein a plurality of the racks (17) are arranged in a plurality of rows, a longitudinal rail (18) arranged along the length direction of the cabinet body (1) is laid between the racks (17) on two adjacent rows on the inner bottom wall of the cabinet body (1), a transverse rail (19) arranged along the width direction of the cabinet body (1) is laid below the racks (17) on the inner bottom wall of the cabinet body (1), and the electrolytic bath (51) is placed on the transverse rail (19).

5. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 4, wherein the bottom end of the electrolytic cell (51) is provided with a moving wheel (20), the moving wheel (20) is in rolling contact with the transverse rail (19).

6. The integrated intelligent water electrolytic oxyhydrogen generator system station according to claim 5, wherein the position of the transverse rail (19) away from the side door (2) is provided with a stop pillar (21) for stopping the moving wheel (20).

7. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 1, wherein the side door (2) is mounted with a cooling fan (22) in wireless electrical connection with the remote management platform (13).

8. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 1, wherein the exhaust pipe (511) extends out of the cabinet body (1) to connect with an external anti-backfire safety conflux cabinet (23).

9. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 1, wherein the front side of the cabinet (1) is provided with a front door (24).

10. The integrated intelligent water electrolysis oxyhydrogen generator system station according to claim 1, wherein the cabinet body (1) is welded by sheet metal.

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