CN220291950U - Distributed photovoltaic power generation structure for coal shed roof - Google Patents

Abstract

The utility model relates to a distributed photovoltaic power generation structure for a coal shed roof, which comprises a coal shed roof, a damping component, a transmission component, a distribution component, a photovoltaic component and four support components. The utility model has the beneficial effects that the vibration reduction effect on the photovoltaic components on the coal shed roof is realized by arranging the vibration reduction component, the stable lifting effect on the coal shed roof is realized by arranging the support component, the photovoltaic components are driven to conveniently adjust different angles to maximally absorb solar light, meanwhile, the transmission component is driven to drive the photovoltaic components on the distribution component to rotate, the maximized absorption of solar light of the photovoltaic panels is further enhanced, the distribution component drives the photovoltaic components to rotate, the effect of uniformly distributing the photovoltaic panels is realized, the light energy is converted into electric energy, the practicability of equipment is increased, and the practical application and operation are facilitated.

Description

Distributed photovoltaic power generation structure for coal shed roof

Technical Field

The utility model relates to the technical field of coal shed roofs, in particular to a distributed photovoltaic power generation structure for a coal shed roof.

Background

Coal, which is called stone coal or graphite before and is called coal after the beginning, is a black solid mineral formed by the action of high temperature and high pressure on plants, and is mainly used as fuel and chemical raw materials, such as coal mines;

in the existing coal mine, the coal shed roof is constructed manually to protect the coal mine, so that the service life of the coal mine is prolonged, however, the constructed coal shed roof cannot be utilized, the photovoltaic panel is arranged at the top of the coal shed roof, and meanwhile, the photovoltaic panel cannot be adjusted at multiple angles, so that the construction cost of the coal shed roof is further increased, the practicability of the coal shed roof is reduced, and the practical application and operation are not facilitated.

The above prior art solutions have the following drawbacks: the coal shed roof that can't utilize to build sets up the photovoltaic board at the top of coal shed roof, also can't carry out multi-angle regulation to the photovoltaic board simultaneously, further increases the cost of coal shed roof construction, reduces the practicality of coal shed roof.

Disclosure of Invention

In view of the foregoing problems in the prior art, a primary object of the present utility model is to provide a distributed photovoltaic power generation structure for a coal canopy.

The technical scheme of the utility model is as follows: the distributed photovoltaic power generation structure comprises a coal shed roof, a damping component, a transmission component, a distribution component, a photovoltaic component and four supporting components, wherein the damping component is arranged on the inner side of the coal shed roof;

the distribution assembly comprises a first rotating shaft and a second rotating shaft, wherein the first rotating shaft is rotationally connected to the inside of the coal shed roof, and the second rotating shaft is rotationally connected to the inside of the coal shed roof and located on two sides of the first rotating shaft.

As a preferred implementation mode, the damping component comprises a placing plate, sliding grooves, sliding blocks and springs, wherein the sliding grooves are formed in two sides of the inner wall of the coal shed roof, the sliding blocks are connected inside the sliding grooves in a sliding mode, the springs are fixedly connected between the sliding blocks and the inner wall of the sliding grooves, and the placing plate is fixedly connected between the two sliding blocks.

As a preferred embodiment, the transmission assembly includes an L-shaped plate fixedly installed at the bottom of the placement plate and a motor fixedly installed at the bottom of the inner side of the L-shaped plate.

As a preferred embodiment, the distribution assembly further comprises a first belt pulley and a second belt pulley, the bottom end of the first rotating shaft is rotationally connected with the top of the placing plate, the bottom end of the second rotating shaft is rotationally connected with the top of the placing plate, the output shaft of the motor extends to the top of the placing plate and is fixedly connected with the first rotating shaft, the first belt pulleys are fixedly installed on the outer side of the first rotating shaft, the second belt pulleys are fixedly installed on the outer side of the second rotating shaft, one of the second belt pulleys is rotationally connected with one of the first belt pulleys through a belt, and the other of the second belt pulleys is rotationally connected with the other of the first belt pulleys through the belt.

As a preferred embodiment, the photovoltaic module includes first dead lever, first electric telescopic handle, first photovoltaic board, second dead lever, second electric telescopic handle and second photovoltaic board, the equal fixed mounting of first dead lever is on the top of first pivot, the equal rotation of first photovoltaic board is connected on the top of first dead lever, the equal rotation of first electric telescopic handle is connected on the both sides on first pivot top, the piston rod of first electric telescopic handle all is connected with the bottom rotation that first photovoltaic board kept away from first dead lever one end, the equal fixed mounting of second dead lever is on the top of second pivot, the equal rotation of second photovoltaic board is connected on the top of second dead lever, the equal rotation of second electric telescopic handle is connected on the both sides on second pivot top, the piston rod of second electric telescopic handle all is connected with the bottom rotation that second photovoltaic board kept away from second dead lever one end.

As a preferred embodiment, the support assembly comprises a third electric telescopic rod and reinforcing rods, wherein the third electric telescopic rods are arranged on two sides of the bottom of the coal shed roof, and piston rods of the third electric telescopic rods are fixedly connected with the bottom of the coal shed roof.

As a preferred implementation mode, the top fixed mounting who places the board has the battery, motor, first electric telescopic handle, first photovoltaic board, second electric telescopic handle, second photovoltaic board, third electric telescopic handle and battery all with external control panel electric connection, first photovoltaic board and second photovoltaic board all with battery electric connection.

Compared with the prior art, the utility model has the advantages and positive effects that,

according to the utility model, the damping assembly is arranged to realize the damping effect on the photovoltaic assembly on the coal shed roof, the supporting assembly is arranged to facilitate the stable lifting effect on the coal shed roof, the photovoltaic assembly is driven to conveniently adjust different angles of the photovoltaic plate to maximally absorb solar energy light, the transmission assembly is driven to drive the photovoltaic assembly on the distribution assembly to rotate, the solar energy absorption of the photovoltaic plate to be maximized is further enhanced, the distribution assembly drives the photovoltaic assemblies to rotate, the effect of uniformly distributing the photovoltaic plate is realized, the light energy is converted into electric energy, the practicability of the device is increased, and the device is beneficial to practical application and operation.

Drawings

FIG. 1 is a perspective view of a distributed photovoltaic power generation structure for a coal canopy;

FIG. 2 is a front cross-sectional view of a distributed photovoltaic power generation structure for a coal canopy;

FIG. 3 is an enlarged view of the position A in FIG. 2 of a distributed photovoltaic power generation structure for a coal shed roof according to the present utility model;

fig. 4 is an enlarged view of B in fig. 2 of a distributed photovoltaic power generation structure for a coal shed roof according to the present utility model.

Legend description: 1. a coal shed roof; 2. placing a plate; 3. a chute; 4. a slide block; 5. a spring; 6. an L-shaped plate; 7. a motor; 8. a first rotating shaft; 9. a second rotating shaft; 10. a first pulley; 11. a second pulley; 12. a first fixing rod; 13. a first electric telescopic rod; 14. a first photovoltaic panel; 15. a second fixing rod; 16. a second electric telescopic rod; 17. a second photovoltaic panel; 18. a third electric telescopic rod; 19. a reinforcing rod; 20. and a storage battery.

Detailed Description

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. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The utility model will be further described with reference to the drawings and the specific embodiments

Example 1

As shown in fig. 1, 2, 3 and 4, the present utility model provides a technical solution: the device comprises a coal shed roof 1, a damping component, a transmission component, a distribution component, a photovoltaic component and four support components, wherein the damping component is arranged on the inner side of the coal shed roof 1 to realize a damping effect; the two supporting components are arranged on two sides of the bottom of the coal shed roof 1, so that a lifting supporting effect is realized; the transmission assembly is arranged at the bottom of the shock absorption assembly, the distribution assembly is arranged between the shock absorption assembly and the inner side of the coal shed roof 1, and the photovoltaic assembly is arranged at the top of the coal shed roof 1, so that the effect of adjusting the photovoltaic plates at different angles to absorb light energy is realized;

the distribution assembly comprises a first rotating shaft 8 and a second rotating shaft 9, wherein the first rotating shaft 8 is rotationally connected to the inside of the coal shed roof 1, and the second rotating shaft 9 is rotationally connected to the inside of the coal shed roof 1 and located on two sides of the first rotating shaft 8.

In this embodiment, through setting up damper, realize carrying out absorbing effect to the photovoltaic module on the coal shed roof 1, through setting up supporting component, the convenience goes up and down the effect to the coal shed roof 1 steadily, through driving the photovoltaic module, can conveniently adjust different angles to the photovoltaic board, come the absorption solar light of maximize, drive transmission assembly simultaneously, drive the photovoltaic module on the distribution subassembly and rotate, further increase the absorption solar light of photovoltaic board maximize, when driving a plurality of photovoltaic modules through the distribution subassembly and rotate, also realized carrying out evenly distributed's effect to the photovoltaic board, convert light energy into electric energy, the practicality of increase equipment, be favorable to practical application and operation.

Example 2

As shown in fig. 1, 2, 3 and 4, the damping component comprises a placing plate 2, a sliding groove 3, sliding blocks 4 and springs 5, wherein the sliding groove 3 is formed in two sides of the inner wall of the coal shed roof 1, the sliding blocks 4 are slidably connected in the sliding groove 3, the springs 5 are fixedly connected between the sliding blocks 4 and the inner wall of the sliding groove 3, and the placing plate 2 is fixedly connected between the two sliding blocks 4.

In this embodiment, through the rocking of placing board 2, drive the inside slider 4 of spout 3 and slide to utilize the elasticity of spring 5, slow down the rocking of placing board 2, realize the absorbing effect.

Wherein, drive assembly includes L template 6 and motor 7, and L template 6 fixed mounting is in the bottom of placing board 2, and motor 7 fixed mounting is in the bottom of L template 6 inboard, through motor 7 on the drive L template 6, carries out the rotation to drive distribution assembly and makes the bedding.

Wherein, distribution subassembly still includes first belt pulley 10 and second belt pulley 11, the bottom of first pivot 8 rotates with the top of placing the board 2 and is connected, the bottom of second pivot 9 is all rotated with the top of placing the board 2 and is connected, the output shaft of motor 7 extends to the top of placing the board 2 and with first pivot 8 fixed connection, first belt pulley 10 is equal fixed mounting in the outside of first pivot 8, the outside of second belt pulley 11 is all fixed mounting at second pivot 9, one of them second belt pulley 11 is rotated through the belt with one of them first belt pulley 10 and is connected, wherein another second belt pulley 11 rotates through the belt with another first belt pulley 10 wherein and is connected, rotate through motor 7's rotation, drive first pivot 8, thereby drive the photovoltaic module on first pivot 8 top and rotate, drive first belt pulley 10 and second belt pulley 11 simultaneously, thereby drive the photovoltaic module on second pivot 9 top and rotate, further increase the absorption solar energy light of photovoltaic module maximize, also realized carrying out even distribution to the photovoltaic board when driving a plurality of photovoltaic modules to rotate through distribution subassembly.

The photovoltaic module comprises a first fixing rod 12, a first electric telescopic rod 13, a first photovoltaic plate 14, a second fixing rod 15, a second electric telescopic rod 16 and a second photovoltaic plate 17, wherein the first fixing rod 12 is fixedly arranged on the top end of the first rotating shaft 8, the first photovoltaic plate 14 is rotationally connected to the top end of the first fixing rod 12, the first electric telescopic rod 13 is rotationally connected to the two sides of the top end of the first rotating shaft 8, a piston rod of the first electric telescopic rod 13 is rotationally connected with the bottom of the first photovoltaic plate 14, which is far away from one end of the first fixing rod 12, a second fixing rod 15 is fixedly arranged on the top end of the second rotating shaft 9, the second photovoltaic plate 17 is rotationally connected to the top end of the second fixing rod 15, the piston rod of the second electric telescopic rod 16 is rotationally connected to the bottom of the second photovoltaic plate 17, which is far away from one end of the second fixing rod 15, the first electric telescopic rod 13 is driven, the first photovoltaic plate 14 is driven to be in a matched with the first fixing rod 12, the second photovoltaic plate 14 is driven to be in a rotatable mode, the second photovoltaic plate 16 is driven to be in a rotatable mode, and the second photovoltaic plate is not rotatable, and the second photovoltaic plate is driven to be the photovoltaic plate to be the maximum, and the photovoltaic assembly can be absorbed by the second photovoltaic plate is conveniently.

Wherein, supporting component includes third electric telescopic handle 18 and stiffener 19, and third electric telescopic handle 18 all sets up the both sides in coal shed roof 1 bottom, and the piston rod of third electric telescopic handle 18 all with coal shed roof 1 bottom fixed connection, through setting up third electric telescopic handle 18, conveniently goes up and down stably coal shed roof 1, through setting up stiffener 19, further increases the stability of coal shed roof 1.

Wherein, place the top fixed mounting of board 2 and have battery 20, motor 7, first electric telescopic handle 13, first photovoltaic board 14, second electric telescopic handle 16, second photovoltaic board 17, third electric telescopic handle 18 and battery 20 all with external control panel electric connection, first photovoltaic board 14 and second photovoltaic board 17 all with battery 20 electric connection, through setting up electric connection, drive equipment more fast.

Working principle:

as shown in fig. 1, fig. 2, fig. 3, fig. 4, in the technical field of coal shed roof, through driving third electric telescopic rod 18, drive coal shed roof 1 and go up and down steadily, and cooperate stiffener 19, further increase the stability of coal shed roof 1, when coal shed roof 1 goes up and down, drive and place the board 2 and rock going up and down, drive the inside slider 4 of spout 3 and slide, and utilize the elasticity of spring 5, slow down the rocking of placing board 2, realize the absorbing effect, through driving first electric telescopic rod 13, and cooperate first dead lever 12, drive first photovoltaic board 14 and overturn, simultaneously, drive second electric telescopic rod 16, and cooperate second dead lever 15, drive second photovoltaic board 17 and overturn, can conveniently adjust different angles to maximize the absorption solar energy, motor 7 on the L template 6 is driven simultaneously, thereby drive first photovoltaic board 14 on top of first pivot 8 rotates, drive first belt pulley 10 and second belt pulley 11 simultaneously rotates, thereby drive second photovoltaic board 17 and carry out the most even photovoltaic module's of photovoltaic distribution through driving second photovoltaic board 9, the photovoltaic module is also realized to the most evenly distributed photovoltaic module.

Finally, it should be noted that: the embodiments described above are only for illustrating the technical solution of the present utility model, and are not limiting; 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 with equivalents; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (7)

1. A distributed photovoltaic power generation structure for coal shed roof, includes coal shed roof (1), damper, drive assembly, distribution subassembly, photovoltaic module and four supporting component, its characterized in that: the damping components are arranged on the inner side of the coal shed roof (1), the two supporting components are arranged on two sides of the bottom of the coal shed roof (1), the transmission components are arranged on the bottom of the damping components, the distribution components are arranged between the damping components and the inner side of the coal shed roof (1), and the photovoltaic components are arranged on the top of the coal shed roof (1);

the distribution assembly comprises a first rotating shaft (8) and a second rotating shaft (9), wherein the first rotating shaft (8) is rotationally connected to the inside of the coal shed roof (1), and the second rotating shaft (9) is rotationally connected to the inside of the coal shed roof (1) and located on two sides of the first rotating shaft (8).

2. A distributed photovoltaic power generation structure for a coal canopy according to claim 1, wherein: the damping component comprises a placing plate (2), a sliding groove (3), sliding blocks (4) and springs (5), wherein the sliding grooves (3) are formed in two sides of the inner wall of a coal shed roof (1), the sliding blocks (4) are slidably connected inside the sliding grooves (3), the springs (5) are fixedly connected between the sliding blocks (4) and the inner wall of the sliding groove (3), and the placing plate (2) is fixedly connected between the two sliding blocks (4).

3. A distributed photovoltaic power generation structure for a coal canopy according to claim 2, wherein: the transmission assembly comprises an L-shaped plate (6) and a motor (7), wherein the L-shaped plate (6) is fixedly arranged at the bottom of the placing plate (2), and the motor (7) is fixedly arranged at the bottom of the inner side of the L-shaped plate (6).

4. A distributed photovoltaic power generation structure for a coal canopy according to claim 3, wherein: the distribution assembly further comprises a first belt pulley (10) and a second belt pulley (11), the bottom end of the first rotating shaft (8) is rotationally connected with the top of the placing plate (2), the bottom end of the second rotating shaft (9) is rotationally connected with the top of the placing plate (2), an output shaft of the motor (7) extends to the top of the placing plate (2) and is fixedly connected with the first belt pulley (8), the first belt pulley (10) is fixedly mounted on the outer side of the first rotating shaft (8), the second belt pulley (11) is fixedly mounted on the outer side of the second rotating shaft (9), one of the second belt pulleys (11) is rotationally connected with one of the first belt pulleys (10) through a belt, and the other second belt pulley (11) is rotationally connected with the other first belt pulley (10) through a belt.

5. A distributed photovoltaic power generation structure for a coal canopy according to claim 4, wherein: the photovoltaic module comprises a first fixing rod (12), a first electric telescopic rod (13), a first photovoltaic plate (14), a second fixing rod (15), a second electric telescopic rod (16) and a second photovoltaic plate (17), wherein the first fixing rod (12) is fixedly installed at the top end of the first rotating shaft (8), the first photovoltaic plate (14) is rotationally connected to the top end of the first fixing rod (12), the first electric telescopic rod (13) is rotationally connected to two sides of the top end of the first rotating shaft (8), a piston rod of the first electric telescopic rod (13) is rotationally connected with the bottom of the first photovoltaic plate (14) far away from one end of the first fixing rod (12), the second fixing rod (15) is fixedly installed at the top end of the second rotating shaft (9), the second electric telescopic rod (16) is rotationally connected to two sides of the top end of the second rotating shaft (9), and the piston rod of the second electric telescopic rod (16) is rotationally connected with the bottom of the second fixing rod (17).

6. A distributed photovoltaic power generation structure for a coal canopy according to claim 1, wherein: the support assembly comprises a third electric telescopic rod (18) and a reinforcing rod (19), wherein the third electric telescopic rod (18) is arranged on two sides of the bottom of the coal shed roof (1), and piston rods of the third electric telescopic rod (18) are fixedly connected with the bottom of the coal shed roof (1).

7. A distributed photovoltaic power generation structure for a coal canopy according to claim 5, wherein: the top fixed mounting who places board (2) has battery (20), motor (7), first electric telescopic handle (13), first photovoltaic board (14), second electric telescopic handle (16), second photovoltaic board (17), third electric telescopic handle (18) and battery (20) all with external control panel electric connection, first photovoltaic board (14) and second photovoltaic board (17) all with battery (20) electric connection.