CN219801965U - Low-carbon optimizing device of wind-light-carbon capture comprehensive energy system - Google Patents

Abstract

The utility model discloses a low-carbon optimizing device of a wind-light-carbon capture integrated energy system, which belongs to the field of carbon capture energy optimization, and comprises a carbon catcher fixedly connected in a chimney, and further comprises a stand column, wherein the top of the stand column is fixedly connected with a mounting box, a transmission and a unit for generating electricity are arranged in the mounting box, the input end of the transmission is fixedly connected with a rotating shaft, the side wall of the rotating shaft is rotatably connected with a blade with a variable angle, the middle part of the stand column is fixedly connected with a mounting plate, a photovoltaic plate is fixedly connected onto the mounting plate, a transformer is arranged at the bottom of the stand column, the unit for generating electricity and the photovoltaic plate in the mounting box are electrically connected with the transformer, and the transformer is electrically connected with the carbon catcher. The utility model optimizes the energy supply to the carbon catcher by adopting wind energy and light energy to provide running electric quantity for the carbon catcher.

Description

Low-carbon optimizing device of wind-light-carbon capture comprehensive energy system

Technical Field

The utility model relates to the technical field of carbon capture energy optimization, in particular to a low-carbon optimization device of a wind-light-carbon capture comprehensive energy system.

Background

The electric power industry is used as a main body of energy consumption, the carbon emission accounts for a large proportion in the total carbon emission, the aim that low-carbon electric power is expected to accelerate the realization of carbon emission reduction is fulfilled, multiple energy sources are coupled in the comprehensive energy source system for combined supply, the requirement of terminal multi-energy load can be met, and the development of a multi-energy complementary comprehensive energy source system plays an important role in realizing low-carbon emission reduction and improving the energy utilization rate.

The carbon catcher is arranged for low carbon, but the existing device basically adopts the direct supply of electric energy of a power plant in the energy supply of the carbon catcher, the unit volume of the carbon catcher is large, the energy consumption is high, and the direct supply of electric energy of the power plant can increase the carbon emission of the power plant, so that the carbon catcher does not meet the low carbon concept.

Disclosure of Invention

The utility model aims to provide a low-carbon optimizing device of a wind-light-carbon capture integrated energy system, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a wind-light-carbon entrapment comprehensive energy system low carbon optimizing apparatus, includes the carbon catcher of fixed connection in the chimney, still includes the stand, the top fixedly connected with mounting box of stand, be equipped with the derailleur in the mounting box and be used for generating set, the input fixedly connected with pivot of derailleur, rotate on the lateral wall of pivot and be connected with the changeable blade of angle, the middle part fixedly connected with mounting panel of stand, fixedly connected with photovoltaic board on the mounting panel, the bottom of stand is equipped with the transformer, the unit and the photovoltaic board and the transformer electric connection that are used for generating in the mounting box, transformer and carbon catcher electric connection.

As a further preferable mode of the technical scheme, the bottom of the blade is fixedly connected with a rotating rod, a rotating hole matched with the rotating rod is formed in the side wall of the rotating shaft, the end part of the rotating rod is fixedly connected with a first bevel gear, the end part of the rotating shaft is fixedly connected with a motor, the output end of the motor is fixedly connected with a driving shaft, and the end part of the driving shaft is fixedly connected with a second bevel gear meshed with the first bevel gear.

As a further preferable mode of the technical scheme, the end part of the rotating shaft is fixedly connected with a protective shell, the motor is fixedly connected in the protective shell, and the outer wall of the protective shell is fixedly connected with an air quantity sensor used for controlling the motor and the rotating shaft.

As a further preferable mode of the technical scheme, the middle part of the mounting plate is rotationally connected with a mounting cylinder, a sweeping rod for sweeping the photovoltaic panel is fixedly connected to the side wall of the mounting cylinder, and a driving mechanism for driving the mounting cylinder to rotate in a reciprocating mode is arranged on the rotating shaft.

As a further preferred of this technical scheme, actuating mechanism includes the disc of fixed connection at the pivot tip, fixedly connected with eccentric rod on the terminal surface of disc, fixedly connected with limiting plate on the lateral wall of stand, the vertical sliding connection in middle part of limiting plate has the slide bar, the top fixedly connected with hollow strip of slide bar, eccentric rod sliding connection is in the hollow strip, the tip fixedly connected with and the baffle of hollow strip sliding connection of eccentric rod.

As a further preferred mode of the technical scheme, the driving mechanism further comprises two limiting rods fixedly connected to the lower portion of the hollow bar, through holes matched with the two limiting rods are formed in the limiting plates, sliding blocks are fixedly connected to the side walls of the sliding rods, and spiral grooves matched with the sliding blocks are formed in the inner walls of the mounting cylinders.

As the further preferred of this technical scheme, the lower surface fixedly connected with piston tube of mounting panel, the bottom fixedly connected with piston plate of slide bar, piston plate sliding connection is in piston tube, the lower part fixedly connected with extraction pipe and the discharge pipe of piston tube, all be equipped with the check valve on extraction pipe and the discharge pipe, just keep away from the one end of piston tube on extraction pipe and the discharge pipe and all be linked together with the derailleur in the mounting box, install the filter core that is used for filtering the interior engine oil of derailleur on the extraction pipe.

The utility model provides a low-carbon optimizing device of a wind-light-carbon capture comprehensive energy system, which has the following beneficial effects:

(1) The utility model optimizes the energy supply to the carbon catcher by adopting wind energy and light energy to provide running electric quantity for the carbon catcher.

(2) According to the utility model, the sweeping rod is driven to sweep the surface of the photovoltaic plate through the rotation of the rotating shaft, so that the surface of the photovoltaic plate is kept clean, the photovoltaic plate can stably receive illumination, and the stable power supply of the photovoltaic plate is ensured.

(3) According to the utility model, the piston cylinder and the filter element are arranged, so that engine oil can be filtered by the filter element arranged on the extraction pipe when flowing in the extraction pipe, further, metal scraps in the engine oil are filtered, the normal operation of the transmission is ensured, further, the energy consumption is reduced when the rotating shaft rotates, and the energy supply efficiency of the carbon catcher is optimized.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of the structure of the disc of the present utility model;

FIG. 3 is a schematic view of the structure of the motor of the present utility model;

FIG. 4 is a schematic view of the structure of the sliding rod of the present utility model;

fig. 5 is a schematic view of the structure of the mounting cylinder of the present utility model.

In the figure: 1. a column; 101. a limiting plate; 11. a mounting box; 12. a rotating shaft; 13. a blade; 14. a rotating rod; 15. a first bevel gear; 16. a protective shell; 17. a motor; 171. an air volume sensor; 18. a drive shaft; 19. a second bevel gear; 2. a mounting plate; 21. a photovoltaic panel; 22. a mounting cylinder; 23. a sweep bar; 24. a disc; 25. an eccentric rod; 26. a baffle; 27. hollow strips; 28. a slide bar; 281. a slide block; 29. a limit rod; 3. a piston cylinder; 31. a piston plate; 32. an extraction tube; 33. a discharge pipe; 34. a one-way valve; 35. a filter element; 4. a transformer; 41. a chimney; 42. a carbon trap.

Detailed Description

The technical solutions in 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.

The utility model provides the technical scheme that: as shown in fig. 1, in this embodiment, a low-carbon optimizing device for a wind-light-carbon capturing integrated energy system includes a carbon capturing device 42 fixedly connected in a chimney 41, and further includes a stand column 1, a top fixedly connected with installation box 11 of the stand column 1 is provided with a transmission and a unit for generating electricity in the installation box 11, an input end of the transmission is fixedly connected with a rotating shaft 12, a blade 13 with a variable angle is rotatably connected on a side wall of the rotating shaft 12, a mounting plate 2 is fixedly connected with a middle part of the stand column 1, a photovoltaic plate 21 is fixedly connected on the mounting plate 2, a transformer 4 is arranged at the bottom of the stand column 1, the unit for generating electricity in the installation box 11 and the photovoltaic plate 21 are electrically connected with the transformer 4, and the transformer 4 is electrically connected with the carbon capturing device 42.

When the external wind force is enough, the wind force blows the blades 13 to enable the rotating shaft 12 to rotate, at the moment, the rotating shaft 12 drives the unit for generating electricity in the installation box 11 to operate, and because the angle of the blades 13 is variable, the blades 13 can be controlled to rotate to a proper angle according to the magnitude and the direction of the wind force, in addition, the photovoltaic panel 21 converts light energy into electric energy, electricity generated by the unit for generating electricity in the installation box 11 and the electricity generated by the photovoltaic panel 21 supply electric energy to the carbon catcher 42 in the chimney 41 after being transformed by the transformer 4, so that carbon dioxide exhausted in the chimney 41 is captured by the carbon catcher 42, and the electric energy generated by the unit for generating electricity in the installation box 11 can be converted into direct current before being connected to the transformer 4 according to requirements.

As shown in fig. 2 and 3, the bottom of the blade 13 is fixedly connected with a rotating rod 14, a rotating hole matched with the rotating rod 14 is formed in the side wall of the rotating shaft 12, the end part of the rotating rod 14 is fixedly connected with a first bevel gear 15, the end part of the rotating shaft 12 is fixedly connected with a motor 17, the output end of the motor 17 is fixedly connected with a driving shaft 18, and the end part of the driving shaft 18 is fixedly connected with a second bevel gear 19 meshed with the first bevel gear 15.

Because the second bevel gear 19 is meshed with the first bevel gear 15, the second bevel gear 19 can drive the first bevel gear 15 to rotate when rotating, the rotating rod 14 fixedly connected with the first bevel gear 15 rotates at the moment, and the rotating rod 14 drives the blades 13 to rotate by a certain angle to adapt to the wind power.

As shown in fig. 3, the end of the rotating shaft 12 is fixedly connected with a protecting shell 16, a motor 17 is fixedly connected in the protecting shell 16, and an air volume sensor 171 for controlling the motor 17 is fixedly connected on the outer wall of the protecting shell 16.

The air quantity sensor 171 is used for detecting the external wind power, when the wind power reaches a certain degree, the rotating shaft 12 is unlocked, the motor 17 is controlled to run, at the moment, the motor 17 drives the second bevel gear 19 to rotate a certain angle through the driving shaft 18, the angle of the blade 13 is further turned over, the wind quantity sensor adapts to the wind power, and when the blade 13 is blown by the wind to drive the rotating shaft 12 to rotate, a unit used for generating electricity in the installation box 11 runs and generates electricity to supply electricity for the carbon catcher 42.

As shown in fig. 2, 4 and 5, the middle part of the mounting plate 2 is rotatably connected with a mounting cylinder 22, a sweeping rod 23 for sweeping the photovoltaic panel 21 is fixedly connected to the side wall of the mounting cylinder 22, and a driving mechanism for driving the mounting cylinder 22 to reciprocally rotate is arranged on the rotating shaft 12.

Can drive sweep bar 23 swing when installation section of thick bamboo 22 rotates, can clean the surface of photovoltaic board 21 when sweep bar 23 swing for the surface of photovoltaic board 21 keeps clean, and then makes photovoltaic board 21 can stably receive illumination, guarantees the stable power supply of photovoltaic board 21.

As shown in fig. 2, 4 and 5, the driving mechanism comprises a disc 24 fixedly connected to the end of the rotating shaft 12, an eccentric rod 25 is fixedly connected to the end surface of the disc 24, a limiting plate 101 is fixedly connected to the side wall of the upright column 1, a sliding rod 28 is vertically and slidingly connected to the middle part of the limiting plate 101, a hollow strip 27 is fixedly connected to the top of the sliding rod 28, the eccentric rod 25 is slidingly connected to the hollow strip 27, and a baffle 26 is fixedly connected to the end of the eccentric rod 25 and slidingly connected to the hollow strip 27.

When the rotating shaft 12 rotates, the disc 24 at the end part of the rotating shaft 12 synchronously rotates, and then the eccentric rod 25 on the end surface of the disc 24 can revolve around the circle center of the rotating disc 24, and then the eccentric rod 25 can slide back and forth in the hollow strip 27, and the baffle 26 is arranged so that the eccentric rod 25 cannot be separated from contact with the hollow strip 27;

as shown in fig. 2, 4 and 5, the driving mechanism further comprises two limiting rods 29 fixedly connected to the lower portion of the hollow bar 27, the limiting plate 101 is provided with through holes matched with the two limiting rods 29, the side wall of the sliding rod 28 is fixedly connected with a sliding block 281, and the inner wall of the mounting cylinder 22 is provided with a spiral groove matched with the sliding block 281.

Because slide bar 28 vertical sliding connection is at the middle part of limiting plate 101, and hollow strip 27 fixed connection is at the top of slide bar 28, and two gag lever posts 29 of the lower part fixed connection of hollow strip 27 vertically slide on two limiting plates 101, and then can drive slide bar 28 vertical reciprocating sliding when eccentric rod 25 reciprocates the slip in hollow strip 27, slide bar 28 can not take place the rotation this moment, and then make slider 281 can follow the internal slip of helicla flute in installation section of thick bamboo 22, can make installation section of thick bamboo 22 rotate when slider 281 slides in the helicla flute in installation section of thick bamboo 22, and then pivoted installation section of thick bamboo 22 can drive sweep bar 23 swing and brush the upper surface of photovoltaic board 21.

As shown in fig. 4, the lower surface of the mounting plate 2 is fixedly connected with a piston cylinder 3, the bottom of the sliding rod 28 is fixedly connected with a piston plate 31, the piston plate 31 is slidably connected in the piston cylinder 3, the lower part of the piston cylinder 3 is fixedly connected with an extraction pipe 32 and a discharge pipe 33, check valves 34 are arranged on the extraction pipe 32 and the discharge pipe 33, one ends, far away from the piston cylinder 3, of the extraction pipe 32 and the discharge pipe 33 are communicated with a transmission in the mounting box 11, and a filter element 35 for filtering engine oil in the transmission is arranged on the extraction pipe 32.

The piston plate 31 fixedly connected to the bottom of the piston rod 28 can be driven to vertically reciprocate synchronously when the slide rod 28 vertically slides, when the piston plate 31 vertically reciprocates in the piston cylinder 3, the pressure in the piston cylinder 3 can be enabled to be alternately positive and negative, and the extraction pipe 32 and the discharge pipe 33 connected to the bottom of the piston cylinder 3 are respectively provided with the one-way valve 34, so that engine oil of the transmission in the mounting box 11 can be extracted by the piston cylinder 3, and then the engine oil extracted by the piston cylinder 3 flows back to the transmission again through the discharge pipe 33, and the engine oil can be filtered by the filter element 35 arranged on the extraction pipe 32 when flowing in the extraction pipe 32, so that metal scraps in the engine oil are filtered, normal operation of the transmission is ensured, and energy consumption during rotation of the rotating shaft 12 is reduced.

The utility model provides a low-carbon optimizing device of a wind-light-carbon capture comprehensive energy system, which has the following specific working principle:

when the external wind force is enough, the wind force blows the blades 13 to enable the rotating shaft 12 to rotate, at the moment, the rotating shaft 12 drives the unit for generating electricity in the installation box 11 to operate, and because the angle of the blades 13 is variable, the blades 13 can be controlled to rotate to a proper angle according to the magnitude and the direction of the wind force, in addition, the photovoltaic panel 21 converts light energy into electric energy, electricity generated by the unit for generating electricity in the installation box 11 and the electricity generated by the photovoltaic panel 21 supply electric energy to the carbon catcher 42 in the chimney 41 after being transformed by the transformer 4, so that carbon dioxide exhausted in the chimney 41 is captured by the carbon catcher 42, and the electric energy generated by the unit for generating electricity in the installation box 11 can be converted into direct current before being connected to the transformer 4 according to requirements.

Because the second bevel gear 19 is meshed with the first bevel gear 15, the second bevel gear 19 can drive the first bevel gear 15 to rotate when rotating, the rotating rod 14 fixedly connected with the first bevel gear 15 rotates at the moment, and the rotating rod 14 drives the blades 13 to rotate by a certain angle to adapt to the wind power.

The air quantity sensor 171 is used for detecting the external wind power, when the wind power reaches a certain degree, the rotating shaft 12 is unlocked, the motor 17 is controlled to run, at the moment, the motor 17 drives the second bevel gear 19 to rotate a certain angle through the driving shaft 18, the angle of the blade 13 is further turned over, the wind quantity sensor adapts to the wind power, and when the blade 13 is blown by the wind to drive the rotating shaft 12 to rotate, a unit used for generating electricity in the installation box 11 runs and generates electricity to supply electricity for the carbon catcher 42.

Can drive sweep bar 23 swing when installation section of thick bamboo 22 rotates, can clean the surface of photovoltaic board 21 when sweep bar 23 swing for the surface of photovoltaic board 21 keeps clean, and then makes photovoltaic board 21 can stably receive illumination, guarantees the stable power supply of photovoltaic board 21.

When the rotating shaft 12 rotates, the disc 24 at the end part of the rotating shaft 12 synchronously rotates, and then the eccentric rod 25 on the end surface of the disc 24 can revolve around the circle center of the rotating disc 24, and then the eccentric rod 25 can slide back and forth in the hollow strip 27, and the baffle 26 is arranged so that the eccentric rod 25 cannot be separated from contact with the hollow strip 27;

because slide bar 28 vertical sliding connection is at the middle part of limiting plate 101, and hollow strip 27 fixed connection is at the top of slide bar 28, and two gag lever posts 29 of the lower part fixed connection of hollow strip 27 vertically slide on two limiting plates 101, and then can drive slide bar 28 vertical reciprocating sliding when eccentric rod 25 reciprocates the slip in hollow strip 27, slide bar 28 can not take place the rotation this moment, and then make slider 281 can follow the internal slip of helicla flute in installation section of thick bamboo 22, can make installation section of thick bamboo 22 rotate when slider 281 slides in the helicla flute in installation section of thick bamboo 22, and then pivoted installation section of thick bamboo 22 can drive sweep bar 23 swing and brush the upper surface of photovoltaic board 21.

The piston plate 31 fixedly connected to the bottom of the piston rod 28 can be driven to vertically reciprocate synchronously when the slide rod 28 vertically slides, when the piston plate 31 vertically reciprocates in the piston cylinder 3, the pressure in the piston cylinder 3 can be enabled to be alternately positive and negative, and the extraction pipe 32 and the discharge pipe 33 connected to the bottom of the piston cylinder 3 are respectively provided with the one-way valve 34, so that engine oil of the transmission in the mounting box 11 can be extracted by the piston cylinder 3, and then the engine oil extracted by the piston cylinder 3 flows back to the transmission again through the discharge pipe 33, and the engine oil can be filtered by the filter element 35 arranged on the extraction pipe 32 when flowing in the extraction pipe 32, so that metal scraps in the engine oil are filtered, normal operation of the transmission is ensured, and energy consumption during rotation of the rotating shaft 12 is reduced.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a wind-light-carbon entrapment comprehensive energy system low carbon optimizing device, includes carbon catcher (42) of fixed connection in chimney (41), its characterized in that: still include stand (1), the top fixedly connected with install bin (11) of stand (1), be equipped with derailleur and the unit that is used for generating electricity in install bin (11), the input fixedly connected with pivot (12) of derailleur, rotationally be connected with blade (13) that the angle is changeable on the lateral wall of pivot (12), the middle part fixedly connected with mounting panel (2) of stand (1), fixedly connected with photovoltaic board (21) on mounting panel (2), the bottom of stand (1) is equipped with transformer (4), unit and photovoltaic board (21) and transformer (4) electric connection that are used for generating electricity in install bin (11), transformer (4) and carbon catcher (42) electric connection.

2. The low-carbon optimizing device of the wind-light-carbon capture integrated energy system according to claim 1, wherein the low-carbon optimizing device is characterized in that: the bottom fixedly connected with bull stick (14) of blade (13), offered on the lateral wall of pivot (12) with bull stick (14) complex change hole, the tip fixedly connected with first bevel gear (15) of bull stick (14), the tip fixedly connected with motor (17) of pivot (12), the output fixedly connected with drive shaft (18) of motor (17), the tip fixedly connected with of drive shaft (18) and second bevel gear (19) of first bevel gear (15) meshing.

3. The low-carbon optimizing device of the wind-light-carbon capture integrated energy system according to claim 2, wherein the low-carbon optimizing device is characterized in that: the end part of the rotating shaft (12) is fixedly connected with a protective shell (16), the motor (17) is fixedly connected in the protective shell (16), and the outer wall of the protective shell (16) is fixedly connected with an air quantity sensor (171) for controlling the motor (17) and the rotating shaft (12).

4. The low-carbon optimizing device of the wind-light-carbon capture integrated energy system according to claim 1, wherein the low-carbon optimizing device is characterized in that: the middle part of mounting panel (2) rotates and is connected with a mounting cylinder (22), be fixedly connected with on the lateral wall of mounting cylinder (22) and be used for cleaning sweep bar (23) of photovoltaic board (21), be equipped with on pivot (12) and be used for driving the reciprocating rotation's of mounting cylinder (22) actuating mechanism.

5. The low-carbon optimizing device for the wind-light-carbon capture integrated energy system according to claim 4, wherein the low-carbon optimizing device is characterized in that: the driving mechanism comprises a disc (24) fixedly connected to the end part of the rotating shaft (12), an eccentric rod (25) is fixedly connected to the end surface of the disc (24), a limiting plate (101) is fixedly connected to the side wall of the upright post (1), a sliding rod (28) is vertically and slidingly connected to the middle part of the limiting plate (101), a hollow strip (27) is fixedly connected to the top of the sliding rod (28), the eccentric rod (25) is slidingly connected to the hollow strip (27), and a baffle (26) is fixedly connected to the end part of the eccentric rod (25) and is slidingly connected to the hollow strip (27).

6. The low-carbon optimizing device for the wind-light-carbon capture integrated energy system according to claim 5, wherein the low-carbon optimizing device is characterized in that: the driving mechanism further comprises two limiting rods (29) fixedly connected to the lower portion of the hollow strip (27), through holes matched with the two limiting rods (29) are formed in the limiting plates (101), sliding blocks (281) are fixedly connected to the side walls of the sliding rods (28), and spiral grooves matched with the sliding blocks (281) are formed in the inner walls of the mounting cylinders (22).

7. The low-carbon optimizing device for the wind-light-carbon capture integrated energy system according to claim 5, wherein the low-carbon optimizing device is characterized in that: the utility model discloses a motor vehicle engine oil filter, including mounting panel (2) and piston tube (33), the lower fixed surface of mounting panel (2) is connected with piston tube (3), the bottom fixedly connected with piston plate (31) of slide bar (28), piston plate (31) sliding connection is in piston tube (3), the lower part fixedly connected with extraction pipe (32) and discharge tube (33) of piston tube (3), all be equipped with check valve (34) on extraction pipe (32) and discharge tube (33), just keep away from one end of piston tube (3) on extraction pipe (32) and discharge tube (33) and all be linked together with the derailleur in mounting box (11), install filter core (35) that are used for filtering the interior engine oil of derailleur on extraction pipe (32).