CN220273540U - Mobile micro-grid photovoltaic container power station - Google Patents

Abstract

The application discloses a portable micro-grid photovoltaic container power station, which comprises a box body and a photovoltaic array stretching mechanism, wherein the box body is connected with a lifting hook through a connecting rope and is sequentially provided with a photovoltaic generator room, a diesel generator room and an energy storage control room; the photovoltaic array stretching mechanism comprises a telescopic supporting shaft, a rotating main shaft, a main supporting frame and a stepped stretching frame, wherein the telescopic supporting shaft is arranged at the bottom of a photovoltaic generator room, a rotating element is arranged on the upper portion of the telescopic supporting shaft, the rotating main shaft is connected with the top end of the telescopic supporting shaft in a mode of being driven by the rotating element to directionally rotate, the main supporting frame comprises a main photovoltaic frame and mounting frames at two ends, the main photovoltaic frame is fixedly arranged at the top of the rotating main shaft, the mounting frames vertically extend downwards from two sides of the main photovoltaic frame and are provided with flattening electric cylinders, the stepped stretching frames are symmetrically arranged at two sides of the main photovoltaic frame and driven by the flattening electric cylinders to be stretched or retracted. The container power station that this application provided uses standardized box as the carrier, and the transportation and the use of being convenient for.

Description

Mobile micro-grid photovoltaic container power station

Technical Field

The utility model relates to the technical field of photovoltaic equipment, in particular to a mobile micro-grid photovoltaic container power station.

Background

With the gradual decrease of traditional fuel energy sources and the increasing prominence of environmental hazards, the long-term sustainable use of renewable energy sources is an urgent problem.

Taking new photovoltaic energy as an example, abundant solar radiation energy is taken as an important energy source, and is one of energy sources which are pollution-free and convenient to use freely. However, at present, photovoltaic power generation is still limited to solar radiation and cannot be performed all day, which means that the persistence of power generation is a problem; in addition, the transportation and handling of the photovoltaic device is relatively cumbersome.

Disclosure of Invention

The utility model has the advantages that the movable micro-grid photovoltaic container power station is provided, wherein a standardized container is used as a carrier, the whole structure is compact, the integrated transportation and the hoisting are convenient, and the sea transportation is particularly convenient;

in addition, a photovoltaic generator room, a diesel generator room and an energy storage control room are arranged in the box body, when solar radiation exists, a solar panel in the photovoltaic generator room is utilized to generate photovoltaic power, when the solar radiation is insufficient, conventional diesel power generation equipment in the diesel generator room is utilized to generate power, and conventional energy storage equipment in the energy storage control room is utilized to store electric energy, so that the situation of insufficient power generation caused by self-deficiency can be effectively solved, and the system can be used as a logistics system matched with ships, highways, tunnels, base stations and the like;

the integrated development saves the trouble of model selection and the problem of system compatibility for users, and saves the cost.

The utility model has the advantages that the movable micro-grid photovoltaic container power station is provided, one or more sections of adjusting shafts can be adjusted to move up and down through the cooperation of the hydraulic pump station and the hydraulic rod, and the light receiving height of the solar panel can be flexibly adjusted, so that the container power station is suitable for being applied to environments with different height requirements, and the application range is wide.

The utility model has the advantages that the movable micro-grid photovoltaic container power station is provided, the telescopic supporting shaft is used as a supporting base point, the solar panel can be supported to a certain height, the rotating main shaft, the main supporting frame and the stepped stretching frame can be driven to directionally rotate through the engagement of the rotating element and the toothed plate on the rotating main shaft, and the solar panel can fully receive solar radiation.

One advantage of the present utility model is to provide a mobile microgrid photovoltaic container power station in which the stepped extension rack can be pulled back to the vicinity of the main support rack by the flattening cylinder when the photovoltaic device is not in use, so that the photovoltaic container power station is convenient to store in a photovoltaic power generator room, has a simple overall structure, is easy to manufacture and form, is convenient to maintain, and is convenient to store in a small space when the photovoltaic device is not in use.

In order to achieve at least one advantage of the utility model, the utility model provides a mobile micro-grid photovoltaic container power station, which comprises a box body and a photovoltaic array stretching mechanism, wherein the box body is provided with a plurality of connecting ropes at the edge position, the other ends of the connecting ropes are connected with lifting hooks, the lifting hooks are positioned right above the box body, the box body is sequentially provided with a photovoltaic power generator room, a diesel power generator room and an energy storage control room along the extending direction, and the top of the box body is provided with a cover plate;

the photovoltaic array stretching mechanism comprises a telescopic supporting shaft, a rotating main shaft, a main supporting frame and a stepped stretching frame, wherein the telescopic supporting shaft is fixedly arranged at the bottom of the photovoltaic generator room in an extending mode along the vertical direction and is close to or located at the central position of the photovoltaic generator room, a rotating element is arranged at the upper part of the telescopic supporting shaft, the rotating main shaft is connected to the top end of the telescopic supporting shaft in a mode that the rotating main shaft can be driven by the rotating element to rotate in the horizontal direction in a directional mode, the main supporting frame comprises a main photovoltaic frame and mounting frames arranged at two ends of the main photovoltaic frame, the main photovoltaic frame is fixedly arranged at the top of the rotating main shaft, the mounting frames are vertically extended downwards from the two sides of the rotating main shaft in a hinged mode, flat electric cylinders are symmetrically hinged to the two sides of the main photovoltaic frame in a hinged mode, the output ends of the flat electric cylinders are respectively hinged to the stepped stretching frames at the two sides, and the main photovoltaic frame and the solar panel can be stretched in the main photovoltaic frame and the stepped frame.

According to the embodiment of the utility model, a hydraulic pump station is arranged in the photovoltaic generator room;

the telescopic support shaft comprises a fixed shaft, a section of adjusting shaft and a plurality of hydraulic rods powered by the hydraulic pump station, wherein the fixed shaft is fixedly installed at the bottom of the photovoltaic generator room through a connecting plate, the adjusting shaft is embedded at the top of the fixed shaft in a manner of being capable of sliding in an up-down directional manner, the hydraulic rods extend in the vertical direction and are fixedly arranged in the circumferential direction of the fixed shaft, and the telescopic ends of the hydraulic rods are connected with the adjusting shaft.

According to an embodiment of the utility model, a guide structure is correspondingly arranged at the joint of the fixed shaft and the adjusting shaft.

According to the embodiment of the utility model, a hydraulic pump station is arranged in the photovoltaic generator room;

the telescopic supporting shaft comprises a fixed shaft, a plurality of sections of adjusting shafts and a plurality of hydraulic rods powered by the hydraulic pump station, wherein the fixed shaft is fixedly installed at the bottom of the photovoltaic generator room through a connecting plate, the plurality of sections of adjusting shafts extend along the vertical direction and are matched in a sleeved mode, the adjusting shafts close to the bottom are embedded at the top of the fixed shaft, the hydraulic rods extend along the vertical direction and are fixedly arranged at the circumference of the fixed shaft and the circumference of the adjusting shafts close to the lower part, and the telescopic ends of the hydraulic rods are correspondingly connected with the adjusting shafts close to the upper part.

According to one embodiment of the utility model, the rotating main shaft is fixedly provided with a toothed plate which extends along the vertical direction and is perpendicular to the rotating main shaft, wherein teeth are uniformly arranged at the bottom of the toothed plate, the rotating element extends along the horizontal direction, and the output end of the rotating element is coaxially connected with a main gear meshed with the teeth.

According to an embodiment of the utility model, the toothed plate comprises a fixing part sleeved on the rotating main shaft and an arc-shaped part integrally arranged at the bottom of the fixing part, and the teeth are uniformly arranged at the bottom of the arc-shaped part.

According to an embodiment of the present utility model, the extension angle of the arc-shaped portion in the arc-shaped direction is 30 ° to 60 °.

According to an embodiment of the utility model, the step-type stretching frame comprises two connecting frames and two stretching frames, wherein the two connecting frames are symmetrically hinged to two sides of the main photovoltaic frame through hinge shafts, the two stretching frames are symmetrically and slidingly connected to the outer sides of the connecting frames by taking the main photovoltaic frame as a center, stretching electric cylinders are symmetrically arranged at the front end and the rear end of the connecting frames, and the telescopic ends of the stretching electric cylinders are connected with the stretching frames.

According to one embodiment of the utility model, the lower part of the connecting frame is provided with a guide groove, and the top of the extending frame is provided with a guide rail matched with the guide groove.

According to an embodiment of the utility model, the step-type stretching frame comprises two connecting frames and at least four stretching frames, wherein the two connecting frames are symmetrically hinged to two sides of the main photovoltaic frame through hinge shafts, the number of the stretching frames is two, the stretching frames are symmetrically and slidingly connected to the outer sides of the connecting frames by taking the main photovoltaic frame as a center, stretching electric cylinders are symmetrically arranged at the front end and the rear end of the connecting frames and the front end and the rear end of the stretching frames close to the inner side, and the stretching ends of the stretching electric cylinders are correspondingly connected with the stretching frames close to the outer sides.

These and other objects, features and advantages of the present utility model will become more fully apparent from the following detailed description.

Drawings

Fig. 1 shows a schematic perspective view of a mobile micro-grid photovoltaic container power station according to a preferred embodiment of the present application.

Fig. 2 is a schematic diagram of a partial structure of a mobile micro-grid photovoltaic container power station according to a preferred embodiment of the present application when not deployed.

Fig. 3 is a schematic diagram showing a partial structure of a mobile micro-grid photovoltaic container power station according to a preferred embodiment of the present application when the mobile micro-grid photovoltaic container power station is deployed.

Fig. 4 shows a schematic perspective view of the stretching structure of the photovoltaic array in the present application when the stretching structure is unfolded.

Fig. 5 shows an enlarged schematic view of the portion a in fig. 4 of the present application.

Fig. 6 shows an enlarged schematic view of the part B in fig. 4 of the present application.

Fig. 7 shows an enlarged schematic view of the C part of fig. 4 of the present application.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the utility model. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art. The basic principles of the utility model defined in the following description may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the utility model.

It will be appreciated by those skilled in the art that in the disclosure of the present specification, the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," etc. refer to an orientation or positional relationship based on that shown in the drawings, which is merely for convenience of description and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, the above terms should not be construed as limiting the present utility model.

It will be understood that the terms "a" and "an" should be interpreted as referring to "at least one" or "one or more," i.e., in one embodiment, the number of elements may be one, while in another embodiment, the number of elements may be plural, and the term "a" should not be interpreted as limiting the number.

Referring to fig. 1 to 7, a mobile micro grid photovoltaic container power plant according to a preferred embodiment of the present utility model will be described in detail below, wherein the mobile micro grid photovoltaic container power plant comprises a box 30 and a photovoltaic array stretching mechanism 40, wherein the box 30 is provided with a plurality of connection ropes 20 at edge positions, and the other ends of the plurality of connection ropes 20 are connected with hooks 10, wherein the hooks 10 are located right above the box 30 to facilitate the lifting of the mobile micro grid photovoltaic container power plant by the hooks 10, thereby facilitating the transportation and installation of the mobile micro grid photovoltaic container power plant, and in addition, the box 30 adopts a standard container design, particularly, the transportation of sea roads. The box body 30 is sequentially provided with a photovoltaic generator room 301, a diesel generator room 302 and an energy storage control room 303 along the extending direction, meanwhile, the box body 30 is provided with a cover plate 31 at the top of the photovoltaic generator room 301, wherein the diesel generator room 302 is used for placing conventional diesel generating equipment, and under the condition that solar radiation is insufficient or no solar radiation, the situation that the photovoltaic generation is insufficient due to the defects of the self is made up by diesel generation, so that the power generation can be continuously performed, the mobile micro-grid photovoltaic container power station can be used as a logistics system matched with ships, highways, tunnels, base stations and the like, and the energy storage control room 303 is mainly used for placing energy storage equipment and control equipment such as batteries, control cabinets and the like;

the photovoltaic array stretching mechanism 40 comprises a telescopic support shaft 50, a rotating main shaft 60, a main support frame 70 and a step-like stretching frame 80, wherein the telescopic support shaft 50 is fixedly arranged at the bottom of the photovoltaic generator room 301 in a vertical direction in an extending manner, and is close to or positioned at the central position of the photovoltaic generator room 301, a rotating element (not shown in the figure) such as a servo motor is arranged at the upper part of the telescopic support shaft 50, wherein the rotating main shaft 60 is connected to the top end of the telescopic support shaft 50 in a manner of being driven by the rotating element to directionally rotate in the horizontal direction, in addition, the main support frame 70 comprises a main photovoltaic frame 71 and mounting frames 72 arranged at two ends of the main photovoltaic frame 71, wherein the main photovoltaic frame 71 is fixedly arranged at the top of the main support frame 60, the mounting frames 72 are vertically extended downwards from the main photovoltaic frame 71 at two sides of the rotating main shaft 60, and are symmetrically hinged at the lower part to be provided with a leveling cylinder 73, the step-like stretching frame 80 is arranged in a hinged manner, the step-like stretching frame 80 is driven by the rotating element to directionally rotate in the horizontal direction, the main support frame 80 can be driven by the rotating main support frame 70, the step-like stretching frame 80 can be driven by the main photovoltaic support frame 80, the step-like stretching frame 80 can be driven by the main support frame 80, the main photovoltaic support frame 80 can be driven by the rotating in the vertical direction, the main photovoltaic frame 80 can be stretched by the main support frame 80, and the main support frame 80 can be stretched by the main photovoltaic frame 80, and the stretching frame can be stretched by the main frame, and the main support frame 80 can be stretched by the main frame, and the stretching frame can be stretched by the main frame, and the stretching frame can and the stretching by the vertical frame and the stretching frame and the vertical. So that the solar panel 90 can perform photovoltaic power generation more efficiently.

As a preferred embodiment, a hydraulic pump station 32 is disposed in the photovoltaic generator room 301;

meanwhile, the telescopic supporting shaft 50 includes a fixed shaft 51, a section of adjusting shaft 52 and a plurality of hydraulic rods 53 powered by the hydraulic pump station, wherein the fixed shaft 51 is fixedly installed at the bottom of the photovoltaic generator room 301 through a connecting plate 54, the adjusting shaft 52 is embedded at the top of the fixed shaft 51 in a manner of being capable of sliding up and down, or is embedded at the top of the fixed shaft 51 in a sleeved sliding fit manner, in addition, the hydraulic rods 53 extend along a vertical direction and are fixedly arranged at the circumference of the fixed shaft 51, and simultaneously, the telescopic ends of the hydraulic rods 53 are connected with the adjusting shaft 52, so that the adjusting shaft 52 is driven to move up and down based on the fixed shaft 51 through the hydraulic rods 53 by utilizing the power provided by the hydraulic pump station 32, and the supporting height of the telescopic supporting shaft 50 is flexibly adjusted, so that the solar panel 90 can better receive solar radiation, or the photovoltaic array stretching mechanism 40 is retracted into the photovoltaic generator room 301.

It is further preferred that the connection between the fixed shaft 51 and the adjusting shaft 52 is correspondingly provided with a guiding structure, for example, one or more guiding grooves extending along the vertical direction are provided in the groove at the top of the fixed shaft 51, and simultaneously, the adjusting shaft 52 is provided with a guiding rail matched with the guiding groove at the outer side wall at the bottom.

As another preferred embodiment, a hydraulic pump station 32 is disposed in the photovoltaic generator room 301;

meanwhile, the telescopic support shaft 50 comprises a fixed shaft 51, a plurality of sections of adjusting shafts 52 and a plurality of hydraulic rods 53 powered by the hydraulic pump station 32, wherein the fixed shaft 51 is fixedly installed at the bottom of the photovoltaic generator room 301 through a connecting plate 54, the plurality of sections of adjusting shafts 52 extend in the vertical direction and are matched in a sleeved mode, the adjusting shafts 52 close to the bottom are embedded at the top of the fixed shaft 51, the hydraulic rods 53 extend in the vertical direction and are fixedly arranged at the circumference of the fixed shaft 51 and the circumference of the adjusting shafts 52 close to the lower part, and meanwhile, the telescopic ends of the hydraulic rods 53 are correspondingly connected with the adjusting shafts 52 close to the upper side, so that on the basis of the power provided by the hydraulic pump station 32, the adjusting shafts 52 close to the bottom can be driven to move up and down through the hydraulic rods 53 close to the adjusting shafts 52 on the bottom, and the telescopic support shaft 50 can be guaranteed to be capable of supporting the sun at a preset solar radiation level. In general, a section of the fixed shaft 51 is provided, and two sections of the adjusting shaft 52 are matched, and obviously, in some special cases, the number of the sections of the adjusting shaft 52 can be increased appropriately to obtain a larger stroke supporting height.

In one embodiment, the rotating spindle 60 is fixedly provided with a toothed plate 61 extending along a vertical direction and perpendicular to the rotating spindle 60, wherein teeth 62 are uniformly arranged at the bottom of the toothed plate 61, meanwhile, the rotating element extends along a horizontal direction, and an output end of the rotating element is coaxially connected with a main gear meshed with the teeth 62, so that the rotating spindle 60 is driven to directionally rotate by the rotating element based on the matching relationship between the main gear and the toothed plate 61, and then the main support 70 and the stepped extension 80 are driven to directionally rotate, so that solar radiation can be received more efficiently.

Further preferably, the toothed plate 61 includes a fixing portion 611 sleeved on the rotating main shaft 60 and an arc portion 612 integrally provided at the bottom of the fixing portion 611, and at the same time, the teeth 62 are uniformly provided at the bottom of the arc portion 612. Further, the inner ring of the fixing portion 611 is provided with a tooth port 613, and the rotating main shaft 60 is provided with a rack engaged with the tooth port 613, so that it is ensured that the toothed plate 61 does not slide relative to the rotating main shaft 60 when the rotating element rotates, and thus the reliability of driving the rotating main shaft 60 can be ensured.

Further preferably, the extension angle of the arc-shaped portion 612 in the arc-shaped direction is 30 ° to 60 °, so that the occupied space of the toothed plate 61 can be sufficiently reduced on the premise of meeting the requirement of rotationally meshing with the main gear, flexible assembly of the toothed plate 61 is facilitated, raw materials can be saved, and cost is reduced.

As a preferred embodiment, the stepped stretching frame 80 includes two connecting frames 81 and two stretching frames 82, wherein the two connecting frames 81 are symmetrically hinged to two sides of the main photovoltaic frame 71 through hinge shafts 83, the two stretching frames 82 are symmetrically slidingly connected to the outer sides of the bottom of the connecting frames 81 with the main photovoltaic frame 71 as a center, stretching cylinders 84 are symmetrically installed at the front and rear ends of the connecting frames 81, and simultaneously the stretching ends of the stretching cylinders 84 are connected to the stretching frames 82, so that the stretching frames 82 can be driven by the stretching cylinders 84 to stretch out in a direction away from the connecting frames 81, thereby providing a larger area for receiving solar radiation, or can be pulled back in a direction approaching to the connecting frames 81, so as to facilitate storing the photovoltaic array stretching mechanism 40 in the photovoltaic power generation machine room 301.

It is further preferable that the lower portion of the connection frame 81 is provided with a guide groove 801, and at the same time, the top of the extension frame 82 is provided with a guide rail 821 matched with the guide groove 801 to perform a guiding function, so as to ensure that the extension cylinder 84 can drive the extension frame 82 to slide in an oriented manner.

As another preferred embodiment, the extension frame 82 may have more, so that a larger area may be extended to receive more radiation per unit time. For example, the stepped stretching frame 80 includes two connecting frames 81 and at least four stretching frames 82, wherein the two connecting frames 81 are symmetrically hinged to two sides of the main photovoltaic frame 71 through hinge shafts 83, the number of the stretching frames 82 is two, the stretching frames 82 are symmetrically and slidingly connected to the outer sides of the bottoms of the connecting frames 81 with the main photovoltaic frame 71 as a center, stretching electric cylinders 84 are symmetrically installed at front and rear ends of the connecting frames 81 and the stretching frames 82 close to the inner side, and the stretching ends of the stretching electric cylinders 84 are correspondingly connected to the stretching frames 82 close to the outer side, so that the stretching frames 82 close to the inner side can be driven to stretch outwards or retract inwards through the stretching electric cylinders 84 close to the inner side, or the stretching frames 82 close to the outer side can be driven to stretch outwards or retract inwards, so that a larger light receiving area can be obtained.

It will be appreciated by persons skilled in the art that the embodiments of the utility model described above and shown in the drawings are by way of example only and are not limiting. The advantages of the present utility model have been fully and effectively realized. The functional and structural principles of the present utility model have been shown and described in the examples and embodiments of the utility model may be modified or practiced without departing from the principles described.

Claims (10)

1. The movable micro-grid photovoltaic container power station is characterized by comprising a box body and a photovoltaic array stretching mechanism, wherein the box body is provided with a plurality of connecting ropes at the edge position, the other ends of the connecting ropes are connected with lifting hooks, the lifting hooks are positioned right above the box body, the box body is sequentially provided with a photovoltaic generator room, a diesel generator room and an energy storage control room along the extending direction, and the top of the photovoltaic generator room is provided with a cover plate;

the photovoltaic array stretching mechanism comprises a telescopic supporting shaft, a rotating main shaft, a main supporting frame and a stepped stretching frame, wherein the telescopic supporting shaft is fixedly arranged at the bottom of the photovoltaic generator room in an extending mode along the vertical direction and is close to or located at the central position of the photovoltaic generator room, a rotating element is arranged at the upper part of the telescopic supporting shaft, the rotating main shaft is connected to the top end of the telescopic supporting shaft in a mode that the rotating main shaft can be driven by the rotating element to rotate in the horizontal direction in a directional mode, the main supporting frame comprises a main photovoltaic frame and mounting frames arranged at two ends of the main photovoltaic frame, the main photovoltaic frame is fixedly arranged at the top of the rotating main shaft, the mounting frames are vertically extended downwards from the two sides of the rotating main shaft in a hinged mode, flat electric cylinders are symmetrically hinged to the two sides of the main photovoltaic frame in a hinged mode, the output ends of the flat electric cylinders are respectively hinged to the stepped stretching frames at the two sides, and the main photovoltaic frame and the solar panel can be stretched in the main photovoltaic frame and the stepped frame.

2. The mobile micro-grid photovoltaic container power station according to claim 1, wherein a hydraulic pump station is arranged in the photovoltaic power generator room;

the telescopic support shaft comprises a fixed shaft, a section of adjusting shaft and a plurality of hydraulic rods powered by the hydraulic pump station, wherein the fixed shaft is fixedly installed at the bottom of the photovoltaic generator room through a connecting plate, the adjusting shaft is embedded at the top of the fixed shaft in a manner of being capable of sliding in an up-down directional manner, the hydraulic rods extend in the vertical direction and are fixedly arranged in the circumferential direction of the fixed shaft, and the telescopic ends of the hydraulic rods are connected with the adjusting shaft.

3. The mobile micro-grid photovoltaic container power station of claim 2, wherein a guiding structure is correspondingly arranged at the joint of the fixed shaft and the adjusting shaft.

4. The mobile micro-grid photovoltaic container power station according to claim 1, wherein a hydraulic pump station is arranged in the photovoltaic power generator room;

the telescopic supporting shaft comprises a fixed shaft, a plurality of sections of adjusting shafts and a plurality of hydraulic rods powered by the hydraulic pump station, wherein the fixed shaft is fixedly installed at the bottom of the photovoltaic generator room through a connecting plate, the plurality of sections of adjusting shafts extend along the vertical direction and are matched in a sleeved mode, the adjusting shafts close to the bottom are embedded at the top of the fixed shaft, the hydraulic rods extend along the vertical direction and are fixedly arranged at the circumference of the fixed shaft and the circumference of the adjusting shafts close to the lower part, and the telescopic ends of the hydraulic rods are correspondingly connected with the adjusting shafts close to the upper part.

5. The mobile micro-grid photovoltaic container power station according to claim 1, wherein the rotating main shaft is fixedly provided with a toothed plate extending along the vertical direction and perpendicular to the rotating main shaft, teeth are uniformly arranged at the bottom of the toothed plate, the rotating element extends along the horizontal direction, and the output end of the rotating element is coaxially connected with a main gear meshed with the teeth.

6. The mobile micro-grid photovoltaic container power station of claim 5, wherein the toothed plate comprises a fixed part sleeved on the rotating main shaft and an arc-shaped part integrally arranged at the bottom of the fixed part, and the teeth are uniformly arranged at the bottom of the arc-shaped part.

7. The mobile microgrid photovoltaic container power station according to claim 6, wherein the extension angle of the arc-shaped portion in the arc-shaped direction is 30 ° to 60 °.

8. The mobile micro-grid photovoltaic container power station according to claim 1, wherein the stepped extension frame comprises two connection frames and two extension frames, wherein the two connection frames are symmetrically hinged to two sides of the main photovoltaic frame through a hinge shaft, the two extension frames are symmetrically and slidingly connected to the outer sides of the connection frames by taking the main photovoltaic frame as a center, extension electric cylinders are symmetrically arranged at the front end and the rear end of the connection frames, and the telescopic ends of the extension electric cylinders are connected with the extension frames.

9. The mobile micro-grid photovoltaic container power station of claim 8, wherein a guide groove is arranged at the lower part of the connecting frame, and a guide rail matched with the guide groove is arranged at the top of the extending frame.

10. The mobile micro-grid photovoltaic container power station according to claim 1, wherein the stepped expansion frame comprises two connecting frames and at least four expansion frames, wherein two connecting frames are symmetrically hinged to two sides of the main photovoltaic frame through hinge shafts, the number of the expansion frames is two, the expansion frames are symmetrically and slidingly connected to the outer sides of the connecting frames by taking the main photovoltaic frame as a center, expansion electric cylinders are symmetrically arranged at the front end and the rear end of the connecting frames and the expansion frames close to the inner side, and the expansion ends of the expansion electric cylinders are correspondingly connected to the expansion frames close to the outer sides.