CN113708236A

CN113708236A - Energy storage device of offshore wind power system

Info

Publication number: CN113708236A
Application number: CN202111259458.5A
Authority: CN
Inventors: 何新东
Original assignee: Nantong Zhuoneng Automation System Co ltd
Current assignee: Nantong Zhuoneng Automation System Co ltd
Priority date: 2021-10-28
Filing date: 2021-10-28
Publication date: 2021-11-26
Anticipated expiration: 2041-10-28
Also published as: CN113708236B

Abstract

The invention discloses an energy storage device of an offshore wind power system, and relates to the technical field of power generation and energy storage. The energy storage device comprises a through groove support, a protective shell is fixed at the top of the through groove support, dust screens are embedded in the front and the back of the protective shell, a protective cover is fixed on the outer side of each dust screen, an energy storage assembly is fixed at the bottom of the inner wall of the protective shell, wave-shaped radiating fins penetrate through the bottom of the energy storage assembly, a transmission cable is fixed at the top of the energy storage assembly, radiating mechanisms for radiating the energy storage assembly are arranged on the left side and the right side of the protective shell, and a cleaning mechanism for cleaning the dust screens is arranged at the top of the energy storage assembly. According to the invention, through the arrangement of the protective shell and the protective cover, when the wind power generation energy storage device is impacted by sea waves, the protective shell protects the energy storage assembly, and the protective cover protects the dust screen, so that the safety of the wind power generation energy storage device in use is improved.

Description

Energy storage device of offshore wind power system

Technical Field

The invention relates to the technical field of power generation and energy storage, in particular to an energy storage device of an offshore wind power system.

Background

Offshore wind power is an important field of renewable energy development, is an important force for promoting wind power technology progress and industry upgrading, is an important measure for promoting energy structure adjustment, and in order to improve the utilization efficiency of electric energy generated by a wind power plant, the requirement of a wind power plant during load peak can be met on the basis of not increasing the power grid capacity investment by using a proper electric energy storage system, and meanwhile, the protection of an electric energy storage device is also very important.

Most of existing offshore wind power generation energy storage devices are directly installed on an offshore platform, and when the wind power generation energy storage devices are impacted by sea waves, water enters the wind power generation energy storage devices, so that potential safety hazards and economic losses are caused, and therefore the offshore wind power generation energy storage devices are provided.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an energy storage device of an offshore wind power system, which solves the problems in the background technology.

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides an offshore wind power system energy memory, includes and leads to the groove support, the top that leads to the groove support is fixed with protective housing, protective housing's front and the back all inlay and be equipped with the dust screen, the outside of dust screen is fixed with the protection casing, protective housing's inner wall bottom is fixed with the energy storage subassembly, the left side and the right side of energy storage subassembly all are fixed with the wave fin, the wave fin runs through the bottom of energy storage subassembly, the top of energy storage subassembly is fixed with transmission cable, protective housing's left side and right side all are provided with and are used for carrying out radiating heat dissipation mechanism to the energy storage subassembly, the top of energy storage subassembly is provided with the useful clean mechanism that carries out the cleanness to the dust screen.

Preferably, the heat dissipation mechanism comprises a hinged plate, the top of the hinged plate is hinged to the outer side of the protective shell, an air bag is fixed to one side, close to the protective shell, of the hinged plate, a nozzle is fixed to one side, close to the protective shell, of the air bag, the nozzle penetrates through and is fixedly mounted on the outer wall of the protective shell, the hinged plate is elastically connected with the protective shell through a reset elastic sheet, a connecting plate is fixed to the bottom of the reset elastic sheet, a spine elastic sheet is fixed to the bottom of the connecting plate, the bottom of the spine elastic sheet is fixed to the top of the through groove support, an arc rod is fixed to one side, close to the protective shell, of the hinged plate, and the arc rod penetrates through and is slidably mounted on the surface wall of the protective shell.

Preferably, clean mechanism includes the returning face plate, the returning face plate has two, two the returning face plate articulates respectively in protective housing's top left side and right side, two relative one side of returning face plate all is provided with jet-propelled subassembly, two through two-way elasticity telescopic link swing joint between the returning face plate, two-way elasticity telescopic link comprises interior pole and outer pole in two, the top of interior pole of two-way elasticity telescopic link is fixed with L shape protruding board, one side that energy storage component was kept away from to two-way elasticity telescopic link's outer pole is fixed with the mount, one side that energy storage component was kept away from to the mount is fixed with the cleaning brush, one side that the mount is close to energy storage component is fixed with the elasticity protruding piece.

Preferably, the air injection assembly comprises a fixed shell, a sliding cavity is formed in the fixed shell, an elastic T-shaped rod is slidably mounted in the sliding cavity, and a hemispherical block is fixed at one end, far away from the energy storage assembly, of the elastic T-shaped rod.

Preferably, the projection portion of the elastic projection piece is in contact with the projection portion of the L-shaped projection plate, and the cleaning brush is in contact with the dust screen.

Preferably, the arc rod is in contact with one side of the turnover plate, which is far away from the energy storage assembly, and the arc rod is in contact with the hemispherical block.

The invention provides an energy storage device of an offshore wind power system. The method has the following beneficial effects:

(1) according to the wind power generation energy storage device, the protective shell and the protective cover are arranged, when the wind power generation energy storage device is impacted by sea waves, the protective shell protects the energy storage assembly, and the protective cover protects the dust screen, so that the problem that potential safety hazards are caused when water enters the wind power generation energy storage device when the sea waves impact the wind power generation energy storage device is solved, and the safety of the wind power generation energy storage device in use is improved.

(2) According to the invention, through the arrangement of the hinged plate, when sea waves impact the hinged plate, the sea waves push the hinged plate to overturn downwards, the reset elastic sheet is compressed, the hinged plate extrudes the air bag, and the air bag ejects gas through the nozzle, so that the gas ejected by the air bag dissipates heat of the energy storage assembly, and the problem of damage caused by overheating when the energy storage assembly is used for a long time is avoided.

(3) According to the energy storage component, due to the arrangement of the wavy radiating fins, when sea waves impact the hinged plate, part of water flows out of the through groove support, and water flow carries out water-cooling heat dissipation on the wavy radiating fins, so that the heat dissipation efficiency of the energy storage component is further improved.

(4) The arc rod is matched with the turnover plate, and in the downward turnover process of the hinged plate, the hinged plate drives the arc rod to turn over, so that the arc rod is abutted against the turnover plate to turn over in the protective shell, the bidirectional elastic telescopic rod is compressed, and the turnover plate turns over air in the protective shell, so that the heat dissipation speed of the energy storage assembly is increased; simultaneously under the cooperation of arc pole and hemisphere piece for the arc pole contradicts hemisphere piece and drives inside the smooth chamber of elasticity T shape pole withdrawal, and elasticity T shape pole promotes gaseous outwards blowout, thereby makes the returning face plate upset in-process, and the set casing is jet-propelled, and blows off the dust on the energy storage component, thereby avoids the dust to pile up on energy storage component, influences the problem of energy storage component heat dispersion.

(5) The invention uses the matching of the turnover plate and the bidirectional elastic telescopic rod, in the turnover process of the turnover plate, the turnover plate drives the bidirectional elastic telescopic rod to move upwards, so that the bidirectional elastic telescopic rod drives the fixing frame and the cleaning brush to move upwards, thereby the cleaning brush cleans the surface of the dust screen, thereby avoiding the problem that the dust screen is blocked by dust after long-term use and the heat dissipation of the energy storage assembly is influenced, further indirectly improving the heat dissipation effect of the energy storage assembly, simultaneously, in the compression process of the bidirectional elastic telescopic rod, the outer rod of the bidirectional elastic telescopic rod drives the L-shaped lug plate to move towards the center, under the matching of the L-shaped lug plate lug and the lug of the elastic lug plate, the L-shaped lug plate is abutted against the elastic lug plate to vibrate, the elastic lug plate drives the fixing frame to vibrate, thereby the cleaning brush shakes off the dust attached to the cleaning brush, and then the cleaning efficiency of the cleaning brush to the dust screen is improved.

Drawings

FIG. 1 is a schematic view of the present invention as a whole;

FIG. 2 is a schematic view in partial cross-section of the present invention as a whole;

FIG. 3 is a schematic view of a heat dissipation mechanism according to the present invention;

FIG. 4 is a schematic view of the cleaning mechanism of the present invention;

FIG. 5 is an enlarged view of the structure at A of FIG. 4 according to the present invention;

fig. 6 is a schematic view of a gas injection assembly of the present invention.

In the figure: 1. a through groove bracket; 2. a protective housing; 3. a protective cover; 4. a transmission cable; 5. a heat dissipation mechanism; 51. a hinge plate; 52. an air bag; 53. a nozzle; 54. resetting the elastic sheet; 55. connecting plates; 56. pricking the elastic sheet by a sharp point; 57. an arc rod; 6. a cleaning mechanism; 61. a turnover plate; 62. a gas injection assembly; 621. a stationary case; 622. a slide chamber; 623. an elastic T-bar; 624. a hemispherical block; 63. a bidirectional elastic telescopic rod; 64. a fixed mount; 65. a cleaning brush; 66. an L-shaped convex plate; 67. an elastic lug piece; 7. a dust screen; 8. an energy storage assembly; 9. wave fin.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example 1

Referring to fig. 1-3, the present invention provides a technical solution: the utility model provides an offshore wind power system energy memory, including leading to groove support 1, the top that leads to groove support 1 is fixed with protective housing 2, protective housing 2's front and back all inlay and are equipped with dust screen 7, when this device is installed on the coast, dust screen 7 can prevent that dust on the coast from entering into the device inside, the outside of dust screen 7 is fixed with protection casing 3, protective housing 2's inner wall bottom is fixed with energy storage component 8, energy storage component 8's left side and right side all are fixed with wave fin 9, wave fin 9 runs through energy storage component 8's bottom, energy storage component 8's top is fixed with transmission cable 4, protective housing 2's left side and right side all are provided with and are used for carrying out radiating heat dissipation mechanism 5 to energy storage component 8, energy storage component 8's top is provided with useful carries out clear clean mechanism 6 to dust screen 7.

The heat dissipation mechanism 5 comprises a hinged plate 51, the top of the hinged plate 51 is hinged to the outer side of the protective shell 2, one side of the hinged plate 51, which is close to the protective shell 2, is fixed with an air bag 52, one side of the air bag 52, which is close to the protective shell 2, is fixed with a nozzle 53, the nozzle 53 penetrates through and is fixedly installed on the outer wall of the protective shell 2, the hinged plate 51 is elastically connected with the protective shell 2 through a reset elastic sheet 54, the bottom of the reset elastic sheet 54 is fixed with a connecting plate 55, the bottom of the connecting plate 55 is fixed with a spine elastic sheet 56, the spine elastic sheet 56 is provided with a plurality of spine elastic sheets, the spine elastic sheets 56 are uniformly distributed at the bottom of the connecting plate 55, the bottom of the spine elastic sheet 56 is fixed at the top of the through groove support 1, one side of the hinged plate 51, which is close to the protective shell 2, is fixed with an arc rod 57, and the arc rod 57 penetrates through and is slidably installed on the surface wall of the protective shell 2.

During the use, when wind power generation energy memory received the wave and assaulted, through the setting of protecting sheathing 2 and protection casing 3 for protecting sheathing 2 protects energy storage component 8, and protection casing 3 protects dust screen 7, thereby when having avoided the wave to assault wind power generation energy memory, inside water entered into wind power generation energy memory, caused the problem of potential safety hazard, and then the security when having improved wind power generation energy memory and using.

Impact wind-powered electricity generation energy memory in-process at the wave, the articulated plate 51 can be strikeed to the wave, make articulated plate 51 upset downwards, the shell fragment 54 that resets is compressed, articulated plate 51 extrusion gasbag 52, gasbag 52 is gaseous through nozzle 53 blowout, thereby make gasbag 52 spun gas dispel the heat to energy storage component 8, thereby energy storage component 8 has been avoided using for a long time, overheated problem that leads to the damage, the setting of wave fin 9 simultaneously, energy storage component 8 and the gaseous area of contact of gasbag 52 spun have been improved, thereby the radiating effect to energy storage component 8 has been promoted.

Meanwhile, when the wave impacts the hinge plate 51, part of water flows out of the through groove support 1, and water cooling is carried out on the wave-shaped radiating fins 9 by water flow, so that the heat dissipation efficiency of the energy storage assembly 8 is further improved, meanwhile, the reset elastic sheet 54 drives the connecting plate 55 to move downwards in the compression process, the connecting plate 55 extrudes the spine elastic sheet 56, spines on the spine elastic sheet 56 are stirred by the spines, the water flow flows on the through groove support 1 more dispersedly, so that the water flow is in full contact with the wave-shaped radiating fins 9, and the heat dissipation effect of the water flow on the wave-shaped radiating fins 9 is further promoted.

Through the setting of protective housing 2 and protection casing 3, when wind-powered electricity generation energy memory received the wave and assaulted for protective housing 2 protects energy storage component 8, and protection casing 3 protects dust screen 7, thereby when having avoided the wave to assault wind-powered electricity generation energy memory, inside water entered into wind-powered electricity generation energy memory, caused the problem of potential safety hazard, and then improved the security when wind-powered electricity generation energy memory used.

Through the setting of articulated plate 51, when the articulated plate 51 is strikeed to the wave, make the wave promote articulated plate 51 and overturn downwards, the shell fragment 54 that resets is compressed, articulated plate 51 extrusion gasbag 52, gasbag 52 passes through nozzle 53 blowout gas, thereby make gasbag 52 spun gas dispel the heat to energy storage component 8, thereby avoided energy storage component 8 to use for a long time, overheated problem that leads to the damage, the setting of wave fin 9 has simultaneously improved energy storage component 8 and the gaseous area of contact of gasbag 52 blowout, thereby the radiating effect to energy storage component 8 has been promoted.

Through the setting of wave fin 9, when the articulated slab 51 can be strikeed to the wave, partly water can flow from leading to groove support 1, rivers carry out water-cooling heat dissipation to wave fin 9, thereby further improved the radiating efficiency to energy storage component 8, simultaneously at the shell fragment 54 that resets by the compression in-process, the shell fragment 54 that resets drives even board 55 and moves down, even board 55 extrudes spine shell fragment 56, make the spine on spine shell fragment 56 stir rivers, make rivers flow on leading to groove support 1 in-process more dispersed, thereby make rivers and wave fin 9 fully contact, and then promoted the radiating effect of rivers to wave fin 9.

Example 2

Referring to fig. 4-6, based on embodiment 1, in this embodiment, the cleaning mechanism 6 includes two turning plates 61, two turning plates 61 are respectively hinged on the left side and the right side of the top of the protective housing 2, the arc rod 57 contacts with one side of the turning plate 61 away from the energy storage assembly 8, air injection assemblies 62 are respectively disposed on opposite sides of the two turning plates 61, the two turning plates 61 are movably connected through two-way elastic telescopic rods 63, two-way elastic telescopic rods 63 are provided, the two-way elastic telescopic rods 63 are respectively disposed on the front side and the back side of the turning plate 61, the two-way elastic telescopic rods 63 are composed of two inner rods and outer rods, an L-shaped convex block plate 66 is fixed on the top of the inner rod of the two-way elastic telescopic rod 63, a fixing frame 64 is fixed on one side of the outer rod of the two-way elastic telescopic rod 63 away from the energy storage assembly 8, and a cleaning brush 65 is fixed on one side of the fixing frame 64 away from the energy storage assembly 8, the cleaning brush 65 is in contact with the dust screen 7, an elastic bump sheet 67 is fixed on one side of the fixing frame 64 close to the energy storage assembly 8, and a bump part of the elastic bump sheet 67 is in contact with a bump part of the L-shaped bump plate 66.

The air injection assembly 62 comprises a fixed shell 621, a sliding cavity 622 is formed in the fixed shell 621, the sliding cavity 622 is provided with a plurality of sliding cavities 622, the sliding cavities 622 are uniformly distributed on the fixed shell 621, an elastic T-shaped rod 623 is slidably mounted in the sliding cavity 622, one end, far away from the energy storage assembly 8, of the elastic T-shaped rod 623 is fixed with a hemispherical block 624, and the arc rod 57 is in contact with the hemispherical block 624.

When the energy storage assembly is used, in the process that the hinged plate 51 is turned downwards, the hinged plate 51 drives the arc rod 57 to turn over, the arc rod 57 is enabled to abut against the turning plate 61 to turn over in the protective shell 2 under the matching of the arc rod 57 and the turning plate 61, the bidirectional elastic telescopic rod 63 is compressed, the turning plate 61 turns over air in the protective shell 2, and therefore the heat dissipation speed of the energy storage assembly 8 is increased; simultaneously under arc pole 57 and hemisphere piece 624 cooperation for inside arc pole 57 contradicts hemisphere piece 624 and drives elasticity T shape pole 623 withdrawal slip chamber 622, and elasticity T shape pole 623 promotes gaseous outside blowout, thereby makes the returning face plate 61 upset in-process, and the stationary housing 621 spouts gas-blastly, and blows off the dust on the energy storage component 8, thereby avoids the dust to pile up on energy storage component 8, influences the problem of energy storage component 8 heat dispersion.

Meanwhile, in the overturning process of the overturning plate 61, the overturning plate 61 drives the bidirectional elastic telescopic rod 63 to move upwards, so that the bidirectional elastic telescopic rod 63 drives the fixing frame 64 and the cleaning brush 65 to move upwards, the cleaning brush 65 cleans the surface of the dust screen 7, the problem that the dust screen 7 is blocked by dust after being used for a long time and the heat dissipation of the energy storage assembly 8 is influenced is solved, the heat dissipation effect of the energy storage assembly 8 is indirectly improved, meanwhile, in the process that the bidirectional elastic telescopic rod 63 is compressed, the outer rod of the bidirectional elastic telescopic rod 63 drives the L-shaped lug plate 66 to move towards the center, under the matching of the lugs of the L-shaped lug plate 66 and the lugs of the elastic lug plate 67, the L-shaped lug plate 66 is abutted against the elastic lug plate 67 to vibrate, the elastic lug plate 67 drives the fixing frame 64 to vibrate accordingly, and the cleaning brush 65 shakes off the dust attached to the cleaning brush 65, thereby improving the cleaning efficiency of the cleaning brush 65 to the dust-proof net 7.

Through the cooperation of the arc rod 57 and the turnover plate 61, in the downward turnover process of the hinged plate 51, the hinged plate 51 drives the arc rod 57 to turn over, so that the arc rod 57 abuts against the turnover plate 61 to turn over in the protective shell 2, the bidirectional elastic telescopic rod 63 is compressed, the turnover plate 61 turns over air in the protective shell 2, and the heat dissipation speed of the energy storage assembly 8 is increased; simultaneously under arc pole 57 and hemisphere piece 624 cooperation for inside arc pole 57 contradicts hemisphere piece 624 and drives elasticity T shape pole 623 withdrawal slip chamber 622, and elasticity T shape pole 623 promotes gaseous outside blowout, thereby makes the returning face plate 61 upset in-process, and the stationary housing 621 spouts gas-blastly, and blows off the dust on the energy storage component 8, thereby avoids the dust to pile up on energy storage component 8, influences the problem of energy storage component 8 heat dispersion.

Through the cooperation of the turnover plate 61 and the bidirectional elastic telescopic rod 63, in the turnover process of the turnover plate 61, the turnover plate 61 drives the bidirectional elastic telescopic rod 63 to move upwards, so that the bidirectional elastic telescopic rod 63 drives the fixing frame 64 and the cleaning brush 65 to move upwards, and the cleaning brush 65 cleans the surface of the dust screen 7, thereby avoiding the problem that the dust screen 7 is blocked by dust after long-term use and influencing the heat dissipation of the energy storage assembly 8, further indirectly improving the heat dissipation effect of the energy storage assembly 8, meanwhile, in the process of compressing the bidirectional elastic telescopic rod 63, the outer rod of the bidirectional elastic telescopic rod 63 drives the L-shaped lug plate 66 to move towards the center, under the cooperation of the lug of the L-shaped lug plate 66 and the lug of the elastic lug sheet 67, the L-shaped lug plate 66 is abutted against the elastic lug sheet 67 to vibrate, the elastic lug sheet 67 drives the fixing frame 64 to vibrate, and accordingly, and the cleaning brush 65 shakes off the dust attached to the cleaning brush 65, thereby improving the cleaning efficiency of the cleaning brush 65 to the dust-proof net 7.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides an offshore wind power system energy memory, includes logical groove support (1), its characterized in that: the top that leads to groove support (1) is fixed with protecting sheathing (2), the front and the back of protecting sheathing (2) all inlay and be equipped with dust screen (7), the outside of dust screen (7) is fixed with protection casing (3), the inner wall bottom of protecting sheathing (2) is fixed with energy storage subassembly (8), the left side and the right side of energy storage subassembly (8) all are fixed with wave fin (9), wave fin (9) run through the bottom of energy storage subassembly (8), the top of energy storage subassembly (8) is fixed with transmission cable (4), the left side and the right side of protecting sheathing (2) all are provided with and are used for carrying out radiating heat dissipation mechanism (5) to energy storage subassembly (8), the top of energy storage subassembly (8) is provided with useful clean mechanism (6) of carrying out cleanness to dust screen (7).

2. An offshore wind power system energy storage device according to claim 1, characterised in that: the heat dissipation mechanism (5) comprises a hinged plate (51), the top of the hinged plate (51) is hinged on the outer side of the protective shell (2), an air bag (52) is fixed on one side of the hinged plate (51) close to the protective shell (2), a nozzle (53) is fixed on one side of the air bag (52) close to the protective shell (2), the nozzle (53) penetrates through and is fixedly arranged on the outer wall of the protective shell (2), the hinged plate (51) is elastically connected with the protective shell (2) through a reset spring sheet (54), a connecting plate (55) is fixed at the bottom of the reset elastic sheet (54), a spine elastic sheet (56) is fixed at the bottom of the connecting plate (55), the bottom of the spine elastic sheet (56) is fixed at the top of the through groove bracket (1), an arc rod (57) is fixed on one side of the hinged plate (51) close to the protective shell (2), the arc rod (57) penetrates through and is slidably mounted on the surface wall of the protective shell (2).

3. An offshore wind power system energy storage device according to claim 2, characterised in that: the cleaning mechanism (6) comprises two turnover plates (61), the two turnover plates (61) are respectively hinged on the left side and the right side of the top of the protective shell (2), air injection assemblies (62) are respectively arranged on the opposite sides of the two turnover plates (61), the two turnover plates (61) are movably connected through a bidirectional elastic telescopic rod (63), the bidirectional elastic telescopic rod (63) consists of two inner rods and an outer rod, an L-shaped convex plate (66) is fixed at the top of the inner rod of the bidirectional elastic telescopic rod (63), a fixing frame (64) is fixed on one side of the outer rod of the bidirectional elastic telescopic rod (63) far away from the energy storage assembly (8), a cleaning brush (65) is fixed on one side of the fixed frame (64) far away from the energy storage component (8), and an elastic convex block sheet (67) is fixed on one side of the fixing frame (64) close to the energy storage assembly (8).

4. An offshore wind power system energy storage device according to claim 3, characterised in that: the air injection assembly (62) comprises a fixed shell (621), a sliding cavity (622) is formed in the fixed shell (621), an elastic T-shaped rod (623) is slidably mounted in the sliding cavity (622), and a hemispherical block (624) is fixed to one end, away from the energy storage assembly (8), of the elastic T-shaped rod (623).

5. An offshore wind power system energy storage device according to claim 4, wherein: the lug part of the elastic lug sheet (67) is in contact with the lug part of the L-shaped lug plate (66), and the cleaning brush (65) is in contact with the dust screen (7).

6. An offshore wind power system energy storage device according to claim 1, characterised in that: the arc rod (57) is in contact with one side, away from the energy storage assembly (8), of the turnover plate (61), and the arc rod (57) is in contact with the hemispherical block (624).