CN219630963U - Plateau oxygen-making equipment - Google Patents

Abstract

The embodiment of the utility model relates to plateau oxygen generating equipment, belongs to the technical field of oxygen generating equipment, and aims to solve the technical problem that electric energy provided by a solar energy conversion device in the related art is unstable. The plateau oxygen-making equipment comprises a container, an oxygen-making system and a photovoltaic power generation energy storage system; the oxygen generating system is positioned in the container; the photovoltaic power generation and energy storage system comprises a photovoltaic module, a photovoltaic control module, an inverter and an energy storage battery, wherein the photovoltaic control module, the inverter and the energy storage battery are positioned in the container, and the photovoltaic module is used for converting solar energy into electric energy; the photovoltaic control module is electrically connected with the photovoltaic assembly; the inverter is electrically connected with the photovoltaic control module and the oxygen generation system; the energy storage battery is electrically connected with the photovoltaic control module and the inverter; the photovoltaic control module is configured to control the photovoltaic assembly to supply power to the oxygen generation system through the inverter, control the photovoltaic assembly to charge the energy storage battery, and control the energy storage battery to supply power to the oxygen generation system through the inverter. The plateau oxygen generating equipment improves the stability of supplying power to an oxygen generating system.

Description

Plateau oxygen-making equipment

Technical Field

The embodiment of the utility model belongs to the technical field of oxygen production equipment, and particularly relates to plateau oxygen production equipment.

Background

In the plateau region, due to low oxygen concentration, altitude reactions and even altitude coma are liable to occur for people who live in the region for a long time from the low altitude region, and people who perform outdoor activities or do physical labor in the region. Therefore, it is necessary to provide high-concentration oxygen for the plateau oxygen generating apparatus for treatment.

In the related art, a plateau oxygen generating device is generally provided with a solar energy conversion device and an oxygen generating system, and the solar energy conversion device can convert solar energy into electric energy to supply power for the oxygen generating system so as to fully utilize solar energy resources in a plateau region.

However, in the plateau oxygen-generating equipment in the related art, the electric energy provided by the solar energy conversion device is unstable, so that stable power supply for the oxygen-generating system is not realized, and the reliability of the plateau oxygen-generating equipment is reduced.

Disclosure of Invention

In view of the above, the embodiments of the present utility model provide a plateau oxygen generating apparatus to solve the technical problem of unstable electric energy provided by a solar energy conversion device in the related art.

The embodiment of the utility model provides plateau oxygen production equipment, which comprises a container, an oxygen production system and a photovoltaic power generation energy storage system; the oxygen generating system is positioned in the container; the photovoltaic power generation and energy storage system comprises a photovoltaic module, a photovoltaic control module, an inverter and an energy storage battery, wherein the photovoltaic control module, the inverter and the energy storage battery are positioned in the container, and the photovoltaic module is used for converting solar energy into electric energy; the photovoltaic control module is electrically connected with the photovoltaic module; the inverter is electrically connected with the photovoltaic control module and the oxygen generation system; the energy storage battery is electrically connected with the photovoltaic control module and the inverter; wherein the photovoltaic control module is configured to control the photovoltaic module to supply power to the oxygen generation system through the inverter, control the photovoltaic module to charge the energy storage battery, and control the energy storage battery to supply power to the oxygen generation system through the inverter.

In the plateau oxygen generating equipment provided by the embodiment of the utility model, the photovoltaic assembly is electrically connected with the photovoltaic control module. The photovoltaic control module is electrically connected with the inverter and the oxygen generation system. The photovoltaic control module is configured to control the photovoltaic module to supply power to the oxygen generation system through the inverter, so that the photovoltaic module can supply power to the oxygen generation system through the inverter after the photovoltaic control module converts light energy into electric energy. And the photovoltaic control module is electrically connected with the energy storage battery, and the photovoltaic control module is configured to control the photovoltaic assembly to charge the energy storage battery, so that the photovoltaic assembly can charge the energy storage battery under the control of the photovoltaic control module when the photovoltaic assembly supplies power to the oxygen generation system through the inverter. In addition, the energy storage battery is also electrically connected with the inverter, and the photovoltaic control module is further configured to control the energy storage battery to supply power to the oxygen generation system through the inverter. When the photovoltaic module cannot stably supply power to the oxygen generation system, the energy storage battery can independently supply power to the oxygen generation system through the inverter under the control of the photovoltaic control module, or supply power to the oxygen generation system together with the photovoltaic module, so that the stability of supplying power to the oxygen generation system is improved, and the reliability of the plateau oxygen generation equipment is improved.

In some implementations, which may include the above embodiments, the photovoltaic assembly includes a top photovoltaic assembly, a first side photovoltaic assembly, and a second side photovoltaic assembly, the top photovoltaic assembly mounted to a top surface of the container; the first side photovoltaic module is arranged on the first side of the container; the second side photovoltaic module is mounted on a second side of the container, and the second side is opposite to the first side.

In some implementations that may include the above embodiments, the plateau oxygen generating apparatus further includes a first mount and a first driving member, the first mount being connected to the first side and being proximate to the top surface, the first mount being hinged to the first side photovoltaic module; the first driving piece is located between the first side photovoltaic module and the first side, one end of the first driving piece is hinged to the first side, and the other end of the first driving piece is hinged to the first side photovoltaic module.

In some implementations that may include the above embodiments, the plateau oxygen generating apparatus further includes a second mount and a second driving member, the second mount being connected to the second side and being proximate to the top surface, the second mount being hinged to the second side photovoltaic module; the second driving piece is located between the second side photovoltaic module and the second side face, one end of the second driving piece is hinged to the second side face, and the other end of the second driving piece is hinged to the second side face photovoltaic module.

In some implementations, which may include the above embodiments, the photovoltaic assembly includes a first support frame and a first photovoltaic panel, the first support frame being connected to the container; the first photovoltaic board is connected to one side of the first support frame, which is opposite to the container, and the first photovoltaic board is electrically connected with the photovoltaic control module.

In some implementations, which may include the above embodiments, the number of first photovoltaic panels is plural, and the plurality of first photovoltaic panels are connected in series with each other.

In some implementations, which may include the above embodiments, the photovoltaic assembly further includes a third drive, a second support, and a second photovoltaic panel connected to the second support, the second support being slidably connected to the first support; the third driving piece is connected with the second supporting frame, and drives the second supporting frame to drive the second photovoltaic panel to slide out relative to the first supporting frame so that the second photovoltaic panel receives solar energy; or driving the second support frame to drive the second photovoltaic panel to slide in relative to the first support frame so that the second photovoltaic panel is shielded by the first photovoltaic panel.

In some implementations, which may include the above embodiments, the second photovoltaic panel is connected in series with the first photovoltaic panel through an optimizer.

In some implementations, which may include the above embodiments, the oxygen generation system is a molecular sieve oxygen generation system.

In some implementations, which may include the above embodiments, the container includes an equipment bay and an oxygen uptake bay that are independent of each other, the equipment bay housing the oxygen generation system, the photovoltaic control module, the inverter, and the energy storage battery; the oxygen inhalation cabin is communicated with the oxygen generation system.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions of the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is apparent that the drawings in the following description are some embodiments of the present utility model, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic layout of a plateau oxygen plant of an embodiment of the present utility model;

FIG. 2 is a schematic diagram showing the connection of the altitude oxygen plant of FIG. 1;

FIG. 3 is a schematic view of a first view of the altitude oxygen plant of FIG. 1;

FIG. 4 is a schematic diagram of the structure of the altitude oxygen plant of FIG. 3 in a left-hand view;

FIG. 5 is a schematic view of the first and second side photovoltaic modules of FIG. 4 in a second view configuration when deployed;

FIG. 6 is a schematic view of the third view angle structure of the first and second side photovoltaic modules of FIG. 4 when deployed;

FIG. 7 is a schematic view of a fourth view angle structure of the first and second side photovoltaic modules of FIG. 4 when deployed;

fig. 8 is a schematic diagram of a connection structure between a second photovoltaic panel and a first photovoltaic panel.

Reference numerals illustrate:

10-a container;

110-equipment bay;

120-an oxygen inhalation cabin;

121-a seat;

130-top surface;

140-a first side;

150-a second side;

20-an oxygen generation system;

30-a photovoltaic power generation and energy storage system;

310-photovoltaic module;

311-a first support frame;

312-a first photovoltaic panel;

313-a second support frame;

314—a second photovoltaic panel;

315-a third driver;

320-top photovoltaic module;

330-a first side photovoltaic module;

331-a first mount;

332-a first driver;

340-a second side photovoltaic module;

341-a second mount;

342-a second driver;

350-a photovoltaic control module;

360-inverter;

370-an energy storage battery;

40-a power supply system;

50-other systems.

Detailed Description

Aiming at the problem that the electric energy provided by the solar energy conversion device in the related art is unstable and cannot supply power for the oxygen generation system stably, the embodiment of the utility model provides plateau oxygen generation equipment which is provided with a photovoltaic power generation and energy storage device, wherein the photovoltaic power generation and energy storage device comprises an energy storage battery connected with a photovoltaic module through a photovoltaic control module, and the energy storage battery is also electrically connected with the oxygen generation system. The energy storage battery can store the electric energy obtained after the photovoltaic module converts the solar energy, and when the photovoltaic module cannot stably supply power for the oxygen generation system, the energy storage battery can supply power for the oxygen generation system or supply power together with the photovoltaic module to the oxygen generation system, so that the stability of power supply for the oxygen generation system is improved, and the reliability of the plateau oxygen generation equipment is improved.

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

First, it should be noted that, in the description of the embodiments of the present utility model, terms such as directions or positional relationships indicated by terms such as "inner", "outer", and the like are based on directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the described devices or components must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the embodiments of the present utility model.

Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", and "a third" may explicitly or implicitly include at least one such feature. In the description of the embodiments of the present utility model, the meaning of "plurality" is at least two, for example, two, three, etc., unless explicitly defined otherwise.

Referring to fig. 1 and 2, an embodiment of the present utility model provides a plateau oxygen generating apparatus, which includes a container 10, an oxygen generating system 20, and a photovoltaic power generation energy storage system 30. An oxygen generating system 20 is located within the container 10. The photovoltaic power generation and energy storage system 30 includes a photovoltaic module 310, and a photovoltaic control module 350, an inverter 360, and an energy storage battery 370 located within the container 10. The photovoltaic module 310 is used to convert solar energy into electrical energy. The photovoltaic control module 350 is electrically connected to the photovoltaic module 310. The inverter 360 is electrically connected to the photovoltaic control module 350 and to the oxygen generation system 20. The energy storage battery 370 is electrically connected with the photovoltaic control module 350 and with the inverter 360. Wherein the photovoltaic control module 350 is configured to control the photovoltaic module 310 to supply power to the oxygen generation system 20 through the inverter 360, to control the photovoltaic module 310 to charge the energy storage battery 370, and to control the energy storage battery 370 to supply power to the oxygen generation system 20 through the inverter 360.

The plateau oxygen generating device of the embodiment of the utility model generates oxygen, because the photovoltaic module 310 is electrically connected with the photovoltaic control module 350. The photovoltaic control module 350 is electrically connected to the inverter 360 and to the oxygen generation system 20. The photovoltaic control module 350 is configured to control the photovoltaic module 310 to supply power to the oxygen generation system 20 through the inverter 360 such that the photovoltaic module 310 can supply power to the oxygen generation system 20 through the inverter 360 after the photovoltaic control module 350 converts the light energy into electrical energy. Also, the photovoltaic control module 350 is electrically connected to the energy storage battery 370, and the photovoltaic control module 350 is configured to control the photovoltaic module 310 to charge the energy storage battery 370, such that the photovoltaic module 310 may charge the energy storage battery 370 under the control of the photovoltaic control module 350 when supplying power to the oxygen generation system 20 through the inverter 360. In addition, the energy storage battery 370 is also electrically connected with the inverter 360, and the photovoltaic control module 350 is further configured to control the energy storage battery 370 to supply power to the oxygen generation system 20 through the inverter 360. When the photovoltaic module 310 cannot supply power to the oxygen generation system 20 stably, for example, the electric energy converted by the photovoltaic module 310 is unstable or solar energy is not available at night, the energy storage battery 370 can supply power to the oxygen generation system 20 independently through the inverter 360 under the control of the photovoltaic control module 350 or supply power to the oxygen generation system 20 together with the photovoltaic module 310, so that the stability of supplying power to the oxygen generation system 20 is improved, and the reliability of the plateau oxygen generation equipment is improved.

Illustratively, when the electrical power generated by the photovoltaic assembly 310 is greater than the load power, the photovoltaic assembly 310 may simultaneously charge the energy storage battery 370 while powering the load. When the electrical power generated by the photovoltaic module 310 is less than the load power, the load is powered by the energy storage battery 370 alone or in combination with the photovoltaic module 310.

In addition, electricity generated by the photovoltaic module 310 is clean energy, and the plateau oxygen generating equipment of the embodiment of the utility model does not generate substances polluting the environment in the operation process, thereby having great significance on the environmental protection effect of the plateau region.

In addition, the plateau oxygen generating equipment of the embodiment of the utility model can supply power to the oxygen generating system 20 without an external power supply, improves the adaptation scene of the plateau oxygen generating equipment, is especially suitable for the fields requiring emergency oxygen supply such as onboard oxygen supply, emergency guarantee, disaster rescue, engineering construction and the like, and is also suitable for application on travel routes in plateau areas. The plateau oxygen generating equipment provided by the embodiment of the utility model does not need to erect cables, avoids the construction cost of a high-capacity power grid, and is convenient for later maintenance and other use.

The container 10 may be placed on the car by lifting, for example, or may be placed stationary in a certain position. Referring to fig. 1, container 10 may include an equipment compartment 110 and an oxygen compartment 120 that are independent of each other. The equipment compartment 110 may house the oxygen generation system 20, the photovoltaic control module 350, the inverter 360, and the energy storage battery 370, and may move with the person requiring oxygen to generate oxygen, so as to ensure that the person requiring oxygen is timely supplied with oxygen. Illustratively, a vibration damping base may be disposed in the equipment compartment 110, and the oxygen generating system 20, the photovoltaic control module 350, the inverter 360, the energy storage battery 370, etc. may be disposed on the vibration damping base, so as to reduce the vibration of the oxygen generating system 20, the photovoltaic control module 350, the inverter 360, the energy storage battery 370, etc. when the container 10 moves, thereby affecting the functions of the altitude oxygen generating equipment. Illustratively, the equipment bay 110 may be provided with a double door to facilitate ingress and egress of equipment and people.

For example, oxygen generation system 20 may be a molecular sieve oxygen generation system. The molecular sieve oxygen generation system can comprise an air compressor, an air storage tank, an oxygen generator, an oxygen storage tank, related pipeline valves and the like.

The oxygen intake compartment 120 may be used as an oxygen intake site or a medical site in an emergency. Oxygen intake compartment 120 is in communication with oxygen generation system 20. Illustratively, a plurality of independent oxygen absorbers may be disposed in the oxygen cabin 120, and the oxygen absorbers are in communication with the oxygen generating system 20, and the plurality of oxygen absorbers are capable of independently absorbing oxygen by a plurality of persons. The oxygen-absorbing cabin 120 may also be provided with an oxygen injection port communicated with the oxygen-making system 20, and the oxygen-making system 20 injects oxygen into the oxygen-absorbing cabin through the oxygen injection port, so that the oxygen-absorbing cabin 120 forms an oxygen-enriched cabin, and people in the oxygen-enriched cabin can absorb oxygen together. Illustratively, a plurality of seats 121 may also be provided within the oxygen cabin 120 for people to rest. Oxygen produced by oxygen production system 20 may also be packaged in oxygen cylinders for transporting the oxygen to other locations of use. The oxygen cabin 120 may be provided with a single-open sealing door for people to get in and out. Oxygen cabin 120 may be provided with ventilation means which may expel dirty air from within oxygen cabin 120.

Referring to fig. 3, the container 10 may include a top surface 130, a first side 140 coupled to the top surface 130, and a second side 150 opposite the first side 140. The top surface 130 and the first side surface 140 and the second side surface 150 may be provided with photovoltaic modules 310, so as to fully utilize the space provided by the container 10, and increase the number of the photovoltaic modules 310, thereby increasing the electric energy converted by the photovoltaic modules 310, and providing sufficient electric energy for the oxygen generating system 20.

For example, referring to fig. 4, 5, 6, and 7, the photovoltaic module 310 may include a first support frame 311 and a first photovoltaic panel 312, the first support frame 311 being connected with the container 10. The first photovoltaic panel 312 is connected to a side of the first support frame 311 facing away from the container 10, and the first photovoltaic panel 312 is electrically connected to the photovoltaic control module 350. The first photovoltaic panel 312 receives light energy and converts the received light energy into electrical energy, and supplies the converted electrical energy to the oxygen generation system 20 through the inverter 360 under the control of the photovoltaic control module 350, or transmits the converted electrical energy to the energy storage battery 370 for storage.

Illustratively, there are a plurality of first photovoltaic panels 312, the plurality of first photovoltaic panels 312 being connected in series with one another, the plurality of first photovoltaic panels 312 being capable of enhancing the light energy received by the photovoltaic module 310, thereby enhancing the electrical energy converted by the photovoltaic module 310.

Illustratively, the photovoltaic module 310 may further include a third driving member 315, a second supporting frame 313, and a second photovoltaic panel 314 connected to the second supporting frame 313, the second supporting frame 313 being slidably connected to the first supporting frame 311. The second photovoltaic panel 314 is connected to the second support bracket 313. The third driving member 315 is connected to the second supporting frame 313, for example, the third driving member 315 may be an electric push rod. The third driving member 315 can drive the second supporting frame 313 to slide relative to the first supporting frame 311. The photovoltaic module 310 has a first state and a second state. When the photovoltaic module 310 is in the first state, the third driving member 315 drives the second supporting frame 313 to drive the second photovoltaic panel 314 to slide out relative to the first supporting frame 311, so that the second photovoltaic panel 314 receives solar energy, thereby increasing the area of the photovoltaic module 310 and improving the power generation efficiency of the photovoltaic module 310. When the photovoltaic module 310 is in the second state, the third driving member 315 drives the second supporting frame 313 to drive the second photovoltaic panel 314 to slide in relative to the first supporting frame 311, so that the second photovoltaic panel 314 is shielded by the first photovoltaic panel 312, thereby reducing the area of the photovoltaic module 310 and facilitating the movement of the container 10. For example, when the container 10 is located on a vehicle, the photovoltaic module 310 may be in the second state during driving of the vehicle, which can improve stability of the vehicle when moving.

For example, the third driving member 315 may be electrically connected with an energy storage battery 370, and the energy storage battery 370 provides the third driving member 315 with electrical energy.

For example, referring to fig. 8, the second photovoltaic panel 314 and the first photovoltaic panel 312 may be connected in series by an optimizer. The optimizer automatically disconnects the connection between the second photovoltaic panel 314 and the first photovoltaic panel 312 when the second photovoltaic panel 314 is obscured by the first photovoltaic panel 312 while the vehicle is in a driving state and a stationary state. The optimizer automatically connects the second photovoltaic panel 314 with the first photovoltaic panel 312 when the second photovoltaic panel 314 is not obscured by the first photovoltaic panel 312. In the related art, the second photovoltaic panel 314 and the first photovoltaic panel 312 are connected through the plug-in connection terminal, and the plug-in connection terminal needs to be connected or disconnected manually. According to the embodiment of the utility model, the automatic disconnection and automatic connection of the second photovoltaic panel 314 and the first photovoltaic panel 312 are realized through the optimizer, so that manual operation can be avoided, and the assembly efficiency of the second photovoltaic panel 314 and the first photovoltaic panel 312 is improved.

For example, referring to fig. 3-7, the photovoltaic module 310 may include a top photovoltaic module 320, a first side photovoltaic module 330, and a second side photovoltaic module 340. The top photovoltaic module 320 is mounted to the top surface 130 of the container 10. For example, the top photovoltaic module 320 may be fixedly mounted to the top surface 130 of the container 10. The first side photovoltaic module 330 is mounted to the first side 140 of the container 10. The second side photovoltaic module 340 is mounted to the second side 150 of the container 10, the second side 150 being opposite the first side 140. So set up, top photovoltaic module 320, first side photovoltaic module 330 and second side photovoltaic module 340 do not have each other and shelter from, can make full use of the space that container 10 provided, increase photovoltaic module 310's area to improve photovoltaic module 310's generating efficiency.

Because the top photovoltaic module 320, the first side photovoltaic module 330 and the second side photovoltaic module 340 may have inconsistent illumination radiation values, if the top photovoltaic module 320, the first side photovoltaic module 330 and the second side photovoltaic module 340 are directly connected in parallel, the light emitting efficiency of the photovoltaic module 310 may be reduced. Illustratively, the top photovoltaic module 320, the first side photovoltaic module 330 and the second side photovoltaic module 340 may be electrically connected to the photovoltaic control module 350 through a maximum power point tracking (Maximum Power Point Tracking, abbreviated as MPPT) solar input interface, so that the top photovoltaic module 320, the first side photovoltaic module 330 and the second side photovoltaic module 340 may work independently without mutual influence, and further, the power generation efficiency of the photovoltaic power generation and energy storage system 30 may be effectively improved.

The plateau oxygen generating apparatus may further include a first mounting base 331 and a first driving member 332, where the first mounting base 331 is connected to the first side 140 and is close to the top surface 130, and the first mounting base 331 is hinged to the first side photovoltaic module 330. The first driving member 332 is located between the first side photovoltaic module 330 and the first side 140, one end of the first driving member 332 is hinged to the first side 140, and the other end of the first driving member 332 is hinged to the first side photovoltaic module 330. Illustratively, the first driver 332 may be an electric putter. The first driving member 332 can drive the first side photovoltaic module 330 to rotate relative to the first side 140, so as to adjust the angle of the first side photovoltaic module 330 relative to the first side 140, so that the first side photovoltaic module 330 can receive as much light energy as possible, thereby improving the conversion efficiency of the first side photovoltaic module 330.

The plateau oxygen generating apparatus may further include a second mount 341 and a second driving member 342, the second mount 341 being connected to the second side 150 and being close to the top surface 130, the second mount 341 being hinged to the second side photovoltaic module 340. The second driving member 342 is located between the second side photovoltaic module 340 and the second side 150, one end of the second driving member 342 is hinged to the second side 150, and the other end of the second driving member 342 is hinged to the second side photovoltaic module 340. Illustratively, the second driver 342 may be an electric push rod. The second driving member 342 may drive the second side photovoltaic module 340 to rotate relative to the second side 150, so as to adjust the angle of the second side photovoltaic module 340 relative to the second side 150, so that the second side photovoltaic module 340 can receive as much light energy as possible, thereby improving the conversion efficiency of the second side photovoltaic module 340.

When the car or container 10 is in a stationary state, the photovoltaic module 310 needs to be oriented to the north in the southern hemisphere and the photovoltaic module 310 needs to be oriented to the south in the northern hemisphere so as to maximize the generated power of the photovoltaic module 310. Illustratively, the angle of the first side photovoltaic module 330 relative to the first side 140 and the angle of the second side photovoltaic module 340 relative to the second side 150 may be manually adjusted. Illustratively, the altitude oxygenerator may further comprise a radiation sensor for measuring light emitted by the sun, and the first driving member 332 and the second driving member 342 may be controlled to adjust an angle of the first side photovoltaic module 330 with respect to the first side 140 and an angle of the second side photovoltaic module 340 with respect to the second side 150 according to a value measured by the radiation sensor. For example, the solar altitude may be obtained by a value measured by the radiation sensor, and according to the solar altitude, the first driving member 332 and the second driving member 342 are controlled such that the first side photovoltaic module 330 and the second side photovoltaic module 340 are parallel to each other and face the sun, so as to improve the power generation efficiency of the first side photovoltaic module 330 and the second side photovoltaic module 340. When the container 10 moves, for example, when the container 10 is transported by an automobile, the first driving member 332 can be controlled to drive the first side photovoltaic module 330 to be attached to the first side 140, and the second driving member 342 can be controlled to drive the second side photovoltaic module 340 to be attached to the second side 150, so that the resistance of the automobile when the container 10 is driven to move is reduced, and the stability of the automobile and the container 10 is improved.

Illustratively, referring to fig. 2, the altitude oxygen plant may further include a power supply system 40, and the power supply system 40 may be a utility, or other energy supplemental power generation system.

Illustratively, referring to fig. 2, the altitude oxygen plant may also include other systems 50, which may be lighting systems, power outlets, and the like.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and not for limiting the same; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (10)

1. A plateau oxygen generating apparatus, characterized by comprising:

a container (10);

-an oxygen production system (20) located within the container (10);

a photovoltaic power generation and energy storage system (30) comprising a photovoltaic module (310), and a photovoltaic control module (350), an inverter (360) and an energy storage battery (370) located within the container (10), the photovoltaic module (310) for converting solar energy into electrical energy; the photovoltaic control module (350) is electrically connected to the photovoltaic module (310); the inverter (360) is electrically connected with the photovoltaic control module (350) and with the oxygen generation system (20); the energy storage battery (370) is electrically connected with the photovoltaic control module (350) and with the inverter (360);

wherein the photovoltaic control module (350) is configured to control the photovoltaic module (310) to supply power to the oxygen generation system (20) through the inverter (360), to control the photovoltaic module (310) to charge the energy storage battery (370), and to control the energy storage battery (370) to supply power to the oxygen generation system (20) through the inverter (360).

2. The altitude oxygen plant of claim 1, wherein the photovoltaic module (310) comprises a top photovoltaic module (320) (310), a first side photovoltaic module (330) and a second side photovoltaic module (340), the top photovoltaic module (320) (310) being mounted to the top surface (130) of the container (10); the first side photovoltaic module (330) is mounted to a first side (140) of the container (10); the second side photovoltaic module (340) is mounted to a second side (150) of the container (10), the second side (150) being opposite the first side (140).

3. The plateau oxygen plant of claim 2, further comprising a first mount (331) and a first drive (332), the first mount (331) being connected to the first side (140) and proximate to the top surface (130), the first mount (331) being hinged to the first side photovoltaic module (330); the first driving piece (332) is located between the first side photovoltaic module (330) and the first side (140), one end of the first driving piece (332) is hinged to the first side (140), and the other end of the first driving piece (332) is hinged to the first side photovoltaic module (330).

4. The plateau oxygen generating apparatus of claim 2, further comprising a second mount (341) and a second driver (342), the second mount (341) being connected to the second side (150) and proximate the top surface (130), the second mount (341) being hinged to the second side photovoltaic module (340); the second driving piece (342) is located between the second side photovoltaic module (340) and the second side (150), one end of the second driving piece (342) is hinged to the second side (150), and the other end of the second driving piece (342) is hinged to the second side photovoltaic module (340).

5. The altitude oxygen plant according to claim 1, characterized in that the photovoltaic module (310) comprises a first support frame (311) and a first photovoltaic panel (312), the first support frame (311) being connected to the container (10); the first photovoltaic panel (312) is connected to one side of the first support frame (311) facing away from the container (10), and the first photovoltaic panel (312) is electrically connected with the photovoltaic control module (350).

6. The altitude oxygen plant according to claim 5, wherein the number of first photovoltaic panels (312) is plural, and a plurality of the first photovoltaic panels (312) are connected in series with each other.

7. The altitude oxygen plant according to claim 5, characterized in that the photovoltaic module (310) further comprises a third driving element (315), a second support frame (313), and a second photovoltaic panel (314) connected to the second support frame (313), the second support frame (313) being slidingly connected to the first support frame (311); the third driving piece (315) is connected with the second supporting frame (313), and the third driving piece (315) drives the second supporting frame (313) to drive the second photovoltaic panel (314) to slide out relative to the first supporting frame (311) so that the second photovoltaic panel (314) receives solar energy; or the second supporting frame (313) is driven to drive the second photovoltaic panel (314) to slide in relative to the first supporting frame (311), so that the second photovoltaic panel (314) is shielded by the first photovoltaic panel (312).

8. The altitude oxygen plant of claim 7, wherein the second photovoltaic panel (314) is connected in series with the first photovoltaic panel (312) by an optimizer.

9. The plateau oxygen generating apparatus of claim 1, wherein the oxygen generating system (20) is a molecular sieve oxygen generating system.

10. The altitude oxygen plant according to claim 1, characterized in that the container (10) comprises a plant compartment (110) and an oxygen uptake compartment (120) independent of each other, the plant compartment (110) housing the oxygen production system (20), the photovoltaic control module (350), the inverter (360) and the energy storage battery (370); the oxygen inhalation cabin (120) is communicated with the oxygen generating system (20).