CN219993828U - Cabinet-mounted wind-solar energy storage power system - Google Patents

Abstract

The utility model provides a cabinet-mounted wind-light power storage system, which relates to the technical field of wind-light power storage, and comprises a wind power device and a wind cabinet; the fan cabinet comprises a fan cabin and a base; one side edge of a side plate of the fan bin is connected with the base through a hinge, and the other side edge of the side plate of the fan bin is respectively connected with a turning plate and a top plate through a hinge; all top plates are stacked and fixed at the top of the fan bin; the wind power device is fixed in the fan bin; the inner sides of the side plates and the turning plate are respectively provided with a photovoltaic module; the base comprises an electric control layer and an energy storage layer; the electric control layer is provided with a control circuit; the energy storage layer is provided with an energy storage device; the photovoltaic module and the wind power device are electrically connected with the control circuit; the control circuit is electrically connected with the energy storage device. The utility model can solve the problems of inconvenient carrying, moving and erection of the wind-solar energy storage power system and great consumption of manpower and material resources, realizes convenient carrying, moving and quick erection and use of the wind-solar energy storage power system, and can be suitable for the power guarantee requirements of various specific occasions.

Description

Cabinet-mounted wind-solar energy storage power system

Technical Field

The utility model relates to the technical field of wind-solar energy storage power, in particular to a cabinet-mounted wind-solar energy storage power system.

Background

Wind energy is taken as clean energy, is an important development direction of new energy, and the wind power generation technology is also an energy technology with mature development and application. The wind energy capturing fan is divided into a horizontal axis fan and a vertical axis fan according to the relative position of the wind wheel shaft and the ground, and compared with the horizontal axis fan with perfect development, the vertical axis fan has the advantages of no need of wind, low noise, low investment, convenient installation and maintenance, long service time, easy airfoil manufacturing and the like in wind energy utilization, and is more and more concerned by people.

The fan is large in size and weight, a plurality of tools or a large amount of manpower are needed to be used for carrying in carrying, and in the carrying process, as the blades and other parts of the fan are directly exposed, the fan is not protected, and is quite easy to collide with to cause damage of the fan.

Disclosure of Invention

Aiming at the problems, the cabinet-mounted wind-light power storage system provided by the utility model can solve the problems of inconvenience in carrying, moving and erecting the wind-light power storage system and consumption of a large amount of manpower and material resources, realizes convenience in carrying, moving and erecting the wind-light power storage system, is quick in erection and use, and can be suitable for power guarantee requirements of various specific occasions.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides a cabinet-mounted wind-light power storage system which is characterized by comprising a wind power device and a wind cabinet; the fan cabinet comprises a fan bin and a base which are sequentially arranged up and down; a side plate of the fan bin, which is close to one side of the base, is connected with the base through a rotary connecting piece; a turning plate is connected to one side edge of the side plate away from the base through a rotary connecting piece; the turning plate can be attached to the inner side surface of the side plate through a rotary connecting piece; a top plate is arranged on the outer side of the turning plate; the top plate is connected with the side plate through a rotary connecting piece; all the top plates are stacked on the top of the fan bin and fixed through a hasp; the wind power device is fixed in the fan bin; the inner side of the side plate and the inner side of the turning plate are both provided with photovoltaic modules; the base comprises an electric control layer and an energy storage layer; the electric control layer is provided with a control circuit; the energy storage layer is provided with an energy storage device; the photovoltaic module and the wind power device are electrically connected with the control circuit; the control circuit is electrically connected with the energy storage device.

The cabinet-mounted wind-solar energy storage power system provided by the utility model preferably further comprises a plurality of support rods; all the support rods are vertically arranged on the inner side edge of the wind machine cabinet; and a cross rod is arranged between the adjacent support rods for fixing.

In the cabinet-mounted wind-solar energy storage power system provided by the utility model, preferably, the outer side surface of the side plate is provided with a plurality of adjusting rods; the side plates are provided with a plurality of limit grooves and pin shafts; the upper end of the adjusting rod is rotatably fixed in the limiting groove through a pin shaft.

In the cabinet-mounted wind-solar energy storage power system provided by the utility model, preferably, the outer side surface of the base is provided with a plurality of support bars which are arranged in parallel in the horizontal direction.

According to the cabinet-mounted wind-solar energy storage power system provided by the utility model, preferably, the bottom of the fan cabinet is provided with a plurality of casters.

According to the cabinet-mounted wind-solar energy storage power system, preferably, the bottom of the fan cabinet is provided with the cavity; the casters are fixed on the inner wall of the cavity through folding connectors.

The cabinet-mounted wind-solar energy storage power system provided by the utility model preferably further comprises a top cover; the top cover is sleeved on the top of the fan bin.

In the cabinet-mounted wind-solar energy storage power system provided by the utility model, preferably, a plurality of ventilation small holes are formed in the top plate and the bottom plate of the electric control layer and the energy storage layer.

In the cabinet-mounted wind-solar energy storage power system provided by the utility model, preferably, the side plates are fixedly provided with the square tube reinforcing ribs in a shape like a Chinese character 'mi'.

The cabinet-mounted wind-light energy storage power system provided by the utility model preferably comprises a wind-light complementary controller, a grid-connected inverter, an alternating current load, a direct current load and an energy manager; the wind power device and the photovoltaic module are electrically connected with the wind-solar complementary controller; the wind-solar complementary controller is electrically connected with the grid-connected inverter; the grid-connected inverter is electrically connected with the alternating current load and the energy manager respectively; the energy manager is in data connection with the energy storage device; the energy storage device is respectively and electrically connected with the direct current load and the alternating current load; the wind-solar complementary controller comprises a double staggered parallel boost and a rectifier; the photovoltaic module is connected with one input port of the double staggered parallel boost, and the wind power device is connected with the other input port of the double staggered parallel boost through the rectifier; the energy storage device comprises an energy storage battery module and an energy storage converter; the energy storage battery module is electrically connected with the energy storage converter; the energy storage battery module is electrically connected with the direct current load; the energy storage alternating current device is electrically connected with the grid-connected inverter and the alternating current load respectively.

The technical scheme has the following advantages or beneficial effects:

the utility model provides a cabinet-mounted wind-light energy storage power system, which comprises a wind power device and a wind cabinet; the fan cabinet comprises a fan bin and a base which are sequentially arranged up and down; a side plate of the fan bin, which is close to one side of the base, is connected with the base through a rotary connecting piece; a turning plate is connected to one side edge of the side plate away from the base through a rotary connecting piece; the turning plate can be attached to the inner side surface of the side plate through a rotary connecting piece; a top plate is arranged on the outer side of the turning plate; the top plate is connected with the side plate through a rotary connecting piece; all the top plates are stacked on the top of the fan bin and fixed through a hasp; the wind power device is fixed in the fan bin; the inner side of the side plate and the inner side of the turning plate are both provided with photovoltaic modules; the base comprises an electric control layer and an energy storage layer; the electric control layer is provided with a control circuit; the energy storage layer is provided with an energy storage device; the photovoltaic module and the wind power device are electrically connected with the control circuit; the control circuit is electrically connected with the energy storage device. The cabinet-mounted wind-light power storage system provided by the utility model can solve the problems of inconvenience in carrying, moving and erecting the wind-light power storage system and consumption of a large amount of manpower and material resources, realizes convenience in carrying, moving and erecting the wind-light power storage system, is quick in erection and use, and can be suitable for power guarantee requirements of various specific occasions.

Drawings

The utility model and its features, aspects and advantages will become more apparent from the detailed description of non-limiting embodiments with reference to the following drawings. Like numbers refer to like parts throughout. The drawings are not intended to be drawn to scale, emphasis instead being placed upon illustrating the principles of the utility model.

Fig. 1 is an open schematic diagram of a packaged wind-solar energy storage power system provided in embodiment 1 of the present utility model;

fig. 2 is a schematic closing diagram of a packaged wind-solar energy storage power system provided in embodiment 1 of the present utility model;

fig. 3 is a schematic circuit connection diagram of a packaged wind-solar energy storage power system provided in embodiment 1 of the present utility model.

Detailed Description

The utility model will now be further described with reference to the accompanying drawings and specific examples, which are not intended to limit the utility model.

Example 1:

as shown in fig. 1-2, the cabinet-mounted wind-light power storage system provided by the embodiment of the utility model comprises a wind power device 1 and a wind cabinet 2; the wind cabinet 2 comprises a wind cabin 21 and a base which are sequentially arranged up and down; also includes a top cover 27; the top cover 27 is sleeved on the top of the fan bin 21; also includes a plurality of support bars 24; all the support rods 24 are vertically arranged on the inner side edge of the wind cabinet 2; a cross bar is arranged between the adjacent support bars 24 for fixation; a side plate 210 of the fan bin 21, which is close to one side of the base, is connected with the base through a hinge; a turning plate 212 is connected to one side of the side plate 210 away from the base through a hinge; the turning plate 212 can be attached to the inner side surface of the side plate 210 through a hinge; the outer side of the turning plate 212 is provided with a top plate 211; the top plate 211 is connected with the side plate 210 by a hinge; all top plates 211 are stacked on top of the fan bin 21 and fixed by a hasp; the wind power device 1 is fixed in the fan bin 21; the inner side of the side plate 210 and the inner side of the turning plate 212 are provided with photovoltaic modules 214; the base comprises an electric control layer 22 and an energy storage layer 23; the electric control layer 22 is provided with a control circuit; the energy storage layer 23 is provided with an energy storage device 231; the photovoltaic module 214 and the wind power device 1 are electrically connected with the control circuit; the control circuit is electrically connected with the energy storage device 231; a plurality of adjusting rods 215 are provided on the outer side surface of the side plate 210; the side plate 210 is provided with a plurality of limit grooves and pin shafts; the upper end of the adjusting rod 215 is rotatably fixed in the limit groove through a pin shaft; a plurality of support bars 216 are arranged on the outer side surface of the base in parallel in the horizontal direction.

During carrying, a worker turns the turning plate 212 inwards to attach the turning plate 212 to the inner side of the side plate 210, then the side plate 210 is folded and vertically placed, the top plate 211 is covered on the upper end of the supporting rod 24, the top plates are mutually stacked and fixed through the buckles, and then the top cover 27 is sleeved on the top of the fan, so that the whole wind-solar energy storage power system forms a closed cabinet, and the wind-solar energy storage power system can be protected; when the wind-solar energy storage power system is required to be opened to work after transportation is completed, a worker takes down the top cover 27, unlocks the buckles between the top plates 211, turns down the side plates 210, supports the side plates 210 by abutting one ends of the adjusting rods 215 far away from the side plates 210 on the supporting rods 216 of the base, adjusts the unfolding angles of the side plates 210 by adjusting the adjusting rods 215 on different supporting rods 216, and turns and unfolds the turning plates 212 outwards by the worker, so that the side plates 210 and the photovoltaic modules 214 on the turning plates 212 all receive sunlight towards the outer sides to realize photovoltaic work.

According to the embodiment, the wind power device 1, the energy storage device 231 and the control circuit are integrally arranged in a box body convenient to transport and move through the wind cabinet 2, wind and light integration is achieved, the wind power device 1 is protected through the openable side plates 210, and the photovoltaic modules 214 with enough areas are effectively arranged by utilizing the areas of the side plates 210 to perform wind and light energy storage; the area of the photovoltaic module 214 is increased through the turning plate 212 which can be opened and closed at a large angle and is attached to the side plate 210, so that the photovoltaic working power generation amount is increased; the expansion angle of the side plate 210 is adjusted by the mutual matching of the adjusting rod 215 and the supporting bar 216, so that the photovoltaic module 214 on the side plate 210 can receive sunlight as much as possible.

The cabinet-mounted wind-light-storage power system provided by the embodiment can solve the problems that the wind-light-storage power system is inconvenient to carry, move and erect and consumes a large amount of manpower and material resources, realizes convenient carrying, moving and quick erection and use of the wind-light-storage power system, and can be suitable for power guarantee requirements of various specific occasions.

For easier and more convenient transportation of the wind-solar energy storage power system, in this example, the bottom of the fan cabinet 2 is provided with a plurality of casters 26; the bottom of the wind machine cabinet 2 is provided with a cavity; casters 26 are secured to the interior walls of the chamber by folding connectors. The manpower consumption in the fan carrying process can be further reduced through the truckles 26, and the short-distance transportation of the fan is facilitated.

Further, in this example, a plurality of ventilation holes 200 are formed in the top plate 211 and the bottom plate of the electric control layer 22 and the energy storage layer 23. The ventilation holes 200 can ventilate the base, so as to prevent the control circuit and the energy storage device 231 in the base from being condensed with water, and cause the circuit to malfunction.

Further, in the present embodiment, the side plate 210 is fixed with square-shaped square-tube reinforcing ribs, so as to strengthen the strength of the side plate 210.

As shown in fig. 3, the control circuit includes a wind-solar complementary controller 31, a grid-connected inverter 32, an ac load 33, a dc load 34, and an energy manager 35; the wind power device 1 and the photovoltaic module 214 are electrically connected with the wind-solar complementary controller 31; the wind-solar complementary controller 31 is electrically connected with the grid-connected inverter 32; grid-connected inverter 32 is electrically connected to ac load 33 and energy manager 35; the energy manager 35 is in data connection with the energy storage device 231; the energy storage device 231 is electrically connected with the direct current load 34 and the alternating current load 33 respectively; the wind-solar complementary controller 31 comprises a double staggered parallel boost311 and a rectifier; the photovoltaic module 214 is connected with one input port of the double staggered parallel boost311, and the wind power device 1 is connected with the other input port of the double staggered parallel boost311 through a rectifier; the energy storage device 231 includes an energy storage battery module 2311 and an energy storage converter 2312; the energy storage battery module 2311 is electrically connected with the energy storage converter 2312; energy storage battery module 2311 is electrically coupled to dc load 34; the energy storage converter 2312 is electrically connected to the grid-connected inverter 32 and the ac load 33, respectively. The energy manager 35 can control the photovoltaic module 214 and the power generated by the wind power plant 1 to be output to the ac load 33, the dc load 34 or the energy storage device 231. The energy storage is embedded into the wind-solar integrated circuit, so that the peak clipping and valley filling functions can be achieved, and the embodiment forms a pattern of complementary power generation and power supply of wind power generation, solar power generation and energy storage integration.

In summary, the utility model provides a cabinet-mounted wind-light power storage system, which can solve the problems of inconvenient transportation, movement and erection of the wind-light power storage system and consumption of a large amount of manpower and material resources, integrates wind power generation, photovoltaic power generation and energy storage, realizes convenient transportation, movement and quick erection and use of the wind-light power storage system, and can be suitable for the power guarantee requirements of various specific occasions.

Those skilled in the art will appreciate that the above-described modifications may be implemented by those skilled in the art in combination with the prior art and the above-described embodiments, and are not described herein. Such modifications do not affect the essence of the present utility model, and are not described herein.

The preferred embodiments of the present utility model have been described above. It is to be understood that the utility model is not limited to the specific embodiments described above, wherein devices and structures not described in detail are to be understood as being implemented in a manner common in the art; any person skilled in the art will make many possible variations and modifications, or adaptations to equivalent embodiments without departing from the technical solution of the present utility model, which do not affect the essential content of the present utility model. Therefore, any simple modification, equivalent variation and modification of the above embodiments according to the technical substance of the present utility model still fall within the scope of the technical solution of the present utility model.

Claims (10)

1. The cabinet-mounted wind-solar energy storage power system is characterized by comprising a wind power device and a wind cabinet;

the fan cabinet comprises a fan bin and a base which are sequentially arranged up and down; a side plate of the fan bin, which is close to one side of the base, is connected with the base through a rotary connecting piece; a turning plate is connected to one side edge of the side plate away from the base through a rotary connecting piece; the turning plate can be attached to the inner side surface of the side plate through a rotary connecting piece; a top plate is arranged on the outer side of the turning plate; the top plate is connected with the side plate through a rotary connecting piece; all the top plates are stacked on the top of the fan bin and fixed through a hasp;

the wind power device is fixed in the fan bin; the inner side of the side plate and the inner side of the turning plate are both provided with photovoltaic modules;

the base comprises an electric control layer and an energy storage layer; the electric control layer is provided with a control circuit; the energy storage layer is provided with an energy storage device; the photovoltaic module and the wind power device are electrically connected with the control circuit; the control circuit is electrically connected with the energy storage device.

2. The cabinet-mounted wind-solar energy-storage power system of claim 1, further comprising a plurality of support rods; all the support rods are vertically arranged on the inner side edge of the wind machine cabinet; and a cross rod is arranged between the adjacent support rods for fixing.

3. The cabinet-mounted wind-solar energy storage power system according to claim 1, wherein a plurality of adjusting rods are arranged on the outer side surface of the side plate; the side plates are provided with a plurality of limit grooves and pin shafts; the upper end of the adjusting rod is rotatably fixed in the limiting groove through a pin shaft.

4. A packaged wind-solar energy storage power system according to claim 3, wherein a plurality of support bars are arranged on the outer side surface of the base in parallel in the horizontal direction.

5. The cabinet-mounted wind-solar energy storage power system of claim 1, wherein the bottom of the wind cabinet is provided with a plurality of casters.

6. The cabinet-mounted wind-solar energy storage power system of claim 5, wherein a cavity is formed at the bottom of the wind cabinet; the casters are fixed on the inner wall of the cavity through folding connectors.

7. The packaged wind-solar energy storage power system of claim 1, further comprising a top cover; the top cover is sleeved on the top of the fan bin.

8. The cabinet-mounted wind-solar energy-storage power system according to claim 1, wherein a plurality of ventilation holes are formed in the top plate and the bottom plate of the electric control layer and the energy storage layer.

9. The cabinet-mounted wind-solar energy storage power system according to claim 1, wherein the side plates are fixedly provided with square tube reinforcing ribs in a shape of a Chinese character 'mi'.

10. The packaged wind-solar energy storage power system of claim 1, wherein the control circuit comprises a wind-solar complementary controller, a grid-connected inverter, an ac load, a dc load, and an energy manager;

the wind power device and the photovoltaic module are electrically connected with the wind-solar complementary controller; the wind-solar complementary controller is electrically connected with the grid-connected inverter; the grid-connected inverter is electrically connected with the alternating current load and the energy manager respectively; the energy manager is in data connection with the energy storage device; the energy storage device is respectively and electrically connected with the direct current load and the alternating current load;

the wind-solar complementary controller comprises a double staggered parallel boost and a rectifier; the photovoltaic module is connected with one input port of the double staggered parallel boost, and the wind power device is connected with the other input port of the double staggered parallel boost through the rectifier;

the energy storage device comprises an energy storage battery module and an energy storage converter; the energy storage battery module is electrically connected with the energy storage converter; the energy storage battery module is electrically connected with the direct current load; the energy storage alternating current device is electrically connected with the grid-connected inverter and the alternating current load respectively.