CN113217286A

CN113217286A - Wind power generation rainwater collection and generator heat dissipation and hydrogen production system

Info

Publication number: CN113217286A
Application number: CN202110584629.5A
Authority: CN
Inventors: 沈剑
Original assignee: Guangzhou Bangge New Energy Co ltd
Current assignee: Huashang Jude Beijing Energy Service Co ltd
Priority date: 2021-05-27
Filing date: 2021-05-27
Publication date: 2021-08-06
Anticipated expiration: 2041-05-27
Also published as: CN113217286B

Abstract

The invention relates to the field of rainwater collection and application of wind driven generators, in particular to a rainwater collection, generator heat dissipation and hydrogen production system for wind power generation. The invention can utilize the collected rainwater to cool the generator; the surplus power and the collected rainwater are used for hydrogen production and storage at the power generation peak value of the wind driven generator, so that the power grid load of wind power generation is relieved; because the wind driven generator is often in remote areas, the invention can provide drinking water for maintenance and other workers.

Description

Wind power generation rainwater collection and generator heat dissipation and hydrogen production system

Technical Field

The invention belongs to the field of rainwater collection and application of wind driven generators, and particularly relates to a rainwater collection, generator heat dissipation and hydrogen production system for wind power generation.

Background

Wind energy is clean renewable energy and the wind energy resources in China are extremely rich, however, the power generation mode of wind power generation causes instability of wind power generation, partial problems can be solved by storing the power output in a storage battery in a peak period, and the pollution generated in the production and recovery processes of the storage battery violates the original purpose of using clean energy. Wind power generators are usually built in areas with low human smoke, and the areas lack some infrastructure, so that maintenance personnel need to carry water for drinking, thereby bringing inconvenience. Meanwhile, a large number of power electronic elements, a switching power supply, a capacitor bank and the like are arranged in the wind generating set, so that a large number of harmonics are generated, and the power grid is overloaded.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a wind power generation rainwater collection and generator heat dissipation and hydrogen production system.

In order to achieve the purpose, the invention adopts the following technical scheme: the utility model provides a wind power generation rainwater is collected and generator heat dissipation and hydrogen manufacturing system, includes the bottom box, the fixed support column that is equipped with of up end of bottom box, the fixed support casing that is equipped with of one end that the bottom box was kept away from to the support column, the one end of support casing is rotated and is connected with fan blade group, its characterized in that: a rainwater collecting port is formed in one side, away from the bottom box body, of the supporting shell, and a rainwater primary filtering and cleaning device is arranged at the lower end of the rainwater collecting port 1; a power generation and heat dissipation device connected with the fan blade group is arranged in the supporting shell, and the power generation and heat dissipation device is positioned in the supporting shell; one side of the power generation and heat dissipation device, which is far away from the fan blade group, is provided with a waterproof wall, a distillation generation component is arranged between the waterproof wall and the rainwater primary filtering and cleaning device, a connecting pipe group is arranged in the supporting column, and a rainwater storage hydrogen production and scale removal component is arranged in the bottom box body.

Preferably, the outer upper end of the rainwater collection port is provided with an inclined collection plate, a first guide block is arranged on the lower side of the part, close to the fan blade group, of the rainwater collection port, and a second guide block of an inclined guide support column is arranged on one side, far away from the fan blade group, of the bottom wall of the support shell.

Preferably, the rainwater primary filtering and cleaning device comprises two vertical plates symmetrically arranged in a support shell, one side of each vertical plate, which is far away from the fan blade group, is fixedly provided with a leakage-proof plate, the upper end of one side, which faces the other vertical plate, of each vertical plate is rotatably provided with a baffle, a torsional spring is arranged at the rotary connection part of each baffle and the vertical plate, and the baffle initially seals the rainwater collecting port; a first opening is formed at the joint of each vertical plate and the upper side of the leakage-proof plate, a first rotating shaft is fixedly arranged on one side, close to the first opening, of the baffle, and a first bevel gear is fixedly connected to one end, located in the first opening, of the first rotating shaft; a rotating support seat is fixedly arranged at the lower part of the first opening on one side of each vertical plate facing the support shell, a second rotating shaft extending up and down is rotatably connected in the rotating support seat, a second bevel gear is fixed at one end of the second rotating shaft close to the first opening, and the first bevel gear and the second bevel gear are in meshing transmission; and a third bevel gear is fixedly arranged at the other end of the second rotating shaft and is connected with a filtering component which is arranged inside the two vertical plates and is close to the bottom surface of the supporting shell.

Preferably, the filtering assembly comprises a filtering plate, a second opening is formed in the lower side of the leakage-proof plate, the filtering plate is rotatably connected to the two vertical plates at the position of the second opening, two ends of the filtering plate are fixedly connected with a third rotating shaft penetrating through the two vertical plates, the middle part of a rod body of the third rotating shaft, which exceeds the two vertical plates, is respectively and fixedly connected with a fourth bevel gear, the fourth bevel gear is in meshing transmission with the third bevel gear, and two ends of the third rotating shaft are respectively and fixedly connected with a rope winding wheel; the filter is close to second open-ended one end fixedly connected with slope setting and stretches out second open-ended deflector, the fixed track casing that is equipped with of filter bilateral symmetry, every slide in the track casing and be equipped with the slider, every be connected with the spring between the track casing of slider and corresponding side and the length direction vertically lateral wall, every the slider is connected with the stay cord towards second open-ended one side, the stay cord other end and rope winding wheel fixed connection, two rotate between the slider and be connected with the clearance roller, support casing back shroud department is equipped with the third opening, the deflector is rotatable to stretch out the third opening.

Preferably, the power generation and heat dissipation device comprises a hub, one side of the hub, which extends out of the support shell, is fixedly connected with a fan blade group along an outer cylindrical surface, a bearing seat is arranged on one side, which is connected with the hub and faces the generator, of the support shell, and the hub and the generator are connected with the main shaft; a first circular gear is arranged on one side, close to the generator, of the middle of the main shaft, a first water suction pump is arranged on the main shaft in the direction towards the bottom box body, an auxiliary shaft is connected between the water suction pump and the second circular gear, the first circular gear and the second circular gear are in meshing transmission, a first connecting pipe is arranged on the lower side of the first water suction pump, and a second connecting pipe is connected to the upper side of the water suction pump; the rotor is fixedly connected to one end, located in the installation shell, of the spindle, the stator arranged around the rotor is fixedly connected to the interior of the installation shell, the radiating pipe is wound on the outer circumferential surface of the stator, and the second connecting pipe is connected with one end of the radiating pipe; the utility model discloses a fan blade group, including rotor, water-stop sheet, cooling tube, radiating tube, circular casing downside is provided with a plurality of watering subassemblies, the water-stop sheet is equipped with the fourth opening with the relative department of rotor, one side fixedly connected with heat conduction ring of water-stop sheet is faced to the rotor, heat conduction ring middle part is provided with circular water-stop sheet, the radiating tube other end stretches out the water-stop sheet, and the radiating tube stretches out the circular casing of one end fixedly connected with of water-stop sheet, the radiating tube is provided with first check valve with the one end that circular casing is connected, it is provided with the fifth axis of rotation to rotate in the circular casing, be provided with evenly distributed's a plurality of first turbine blades in the fifth axis of rotation, circular casing is located the upside position of heat conduction ring, the circular casing downside is provided with a plurality of watering subassemblies, circular casing is equipped with the third connecting pipe towards one side of fan blade group, be provided with the second check valve in the third connecting pipe.

Preferably, the watering subassembly is including the fixed tubaeform opening that sets up in circular casing towards heat conduction ring one side, tubaeform opening and the inside link up of circular casing, tubaeform opening internal rotation is connected with the pendulum rod, the hammer is broken up to one side fixedly connected with of pendulum rod towards heat conduction ring, the pendulum rod is equipped with the torsional spring with tubaeform opening rotation junction.

Preferably, the distillation generating component comprises an inverted-triangular condensation cone fixedly arranged on the mounting shell and located at the upper side of the heat conducting circular ring, a conical water receiving opening is formed in the lower side of the gravity center of the condensation cone, and a fourth connecting pipe is communicated with the lower side of the conical water receiving opening.

Preferably, the rainwater storage hydrogen production part comprises a primary filter tank arranged inside the bottom tank body, a filtered water storage tank is arranged on the lower side of the primary filter tank, the filtered water storage tank and the primary filter tank are connected to a fifth connecting pipe, a condensed water storage tank is arranged on the lower side of the filtered water storage tank, a second water pump is arranged at the bottom of the condensed water storage tank, the second water pump is connected with a sixth connecting pipe towards the hydrogen production tank, the other end of the sixth connecting pipe is connected with the hydrogen production tank, a hydrogen production part is arranged at the bottom of the hydrogen production tank, and an exhaust pipe is arranged on the hydrogen production part towards the outer side of the bottom tank body; the hydrogen production case upside is provided with the hydrogen bin, the hydrogen bin is connected with the hydrogen production case and is connected with the seventh connecting pipe.

The preferable scale removing part comprises a rainwater pipe inside a supporting column, a plurality of second turbine blades are arranged inside one end, connected with the primary filter box, of the rainwater pipe, the second turbine blades are uniformly distributed on the outer circumferential surface of a sixth rotating shaft, the sixth rotating shaft extends towards one side of the primary filter box and is connected with a second bearing seat, the bearing seat is arranged on one side of the primary filter box, facing the hydrogen storage box, and the sixth rotating shaft extends towards one side of the hydrogen storage box and is connected with a fifth bevel gear; a third bearing seat is arranged at the bottom of the bottom box body, a seventh rotating shaft is connected to the upper side of the third bearing seat, a sixth bevel gear is arranged on the upper side of the seventh rotating shaft, the sixth bevel gear is in meshing transmission with a fifth bevel gear, a seventh bevel gear is arranged on the seventh rotating shaft between the sixth bevel gear and the third bearing seat, the seventh bevel gear is arranged between the sixth bevel gear and the third bearing seat, an eighth bevel gear is arranged in the seventh bevel gear in the direction of the water filtering storage box, the seventh bevel gear is in meshing transmission with the eighth bevel gear, an eighth rotating shaft is arranged in the eighth bevel gear in the direction of the water filtering storage box, and a fourth bearing seat is arranged at the joint of the eighth rotating shaft and the water filtering storage box; the eighth axis of rotation stretches out towards the drainage bin and is connected with drainage bin lateral wall, the circumference surface of eighth axis of rotation in the drainage bin is provided with scale removal helical blade, the drainage bin is provided with the incrustation scale accumulation box towards bottom box lateral wall direction.

Preferably, the support column is provided with a rainwater pipe with half volume, the upper side of the rainwater pipe is communicated with the lower part of the filtering component, and the lower side of the rainwater pipe is connected with one surface of the primary filtering box facing the hydrogen storage box; a condensate pipe is arranged in the center of the support column, the upper side of the condensate pipe is connected with one end of a fourth connecting pipe, and the lower side of the condensate pipe is connected with a condensate water storage tank towards the direction of the hydrogen production tank; the support column is provided with a first water filter pipe, the upper side of the first water filter pipe is connected with one end of a first connecting pipe, and the lower side of the first water filter pipe is communicated with the water filtering storage tank towards the hydrogen production tank; the support column is provided with the second strainer, the second strainer upside is connected with third connecting pipe one end, second strainer downside drainage bin communicates with each other towards hydrogen manufacturing case direction.

Has the advantages that:

1. according to the invention, the rainwater collecting port baffle is opened by utilizing the potential energy of rainwater, the primary filter plate keeps horizontally filtering the rainwater, the baffle is closed when no rainwater exists, the accumulation of wastes at the primary filtering part is reduced, and meanwhile, the primary filter plate is lifted to remove the wastes;

2. the invention utilizes the power of the generator to extract and collect the filtered rainwater to refrigerate the generator, and simultaneously sprays water to the external heat dissipation device and collects condensed water, and the collected condensed water can be used as a resource for the reaction of drinking water and electrolyzed water of maintenance personnel;

3. the scale removing assembly is arranged to remove scale, and the water turbine drives the removing ring to remove the scale in the refrigeration water storage component by utilizing the potential energy of the water outlet;

4. the invention is provided with the water electrolysis device, and the surplus electric power and the collected whole distilled water are utilized to carry out water electrolysis reaction to produce hydrogen and then are stored when the generator runs at the peak.

Drawings

The invention is further explained below with reference to the figures and examples:

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a cross-sectional view taken at A-A of FIG. 2;

FIG. 4 is an enlarged view of a portion of FIG. 3 at C;

FIG. 5 is a partial cross-sectional view taken at B-B of FIG. 2;

FIG. 6 is a schematic isometric sectional view of the rainwater primary filtering and cleaning device of the present invention;

FIG. 7 is an enlarged view of a portion of FIG. 6 at D;

FIG. 8 is a perspective view of the primary rainwater filtering and cleaning device of the present invention in another direction;

fig. 9 is a front view of the rainwater primary filtering and cleaning device of the present invention.

In the figure: a rainwater collecting port 1, a rainwater primary filtering and cleaning device 2, a power generation and heat dissipation device 3, a distillation generating component 4, a supporting column 5, a bottom box 8, a supporting shell 9, a fan blade group 10, an inclined collecting plate 101, a baffle plate 103, a first bevel gear 104, a leak-proof plate 105, a second bevel gear 106, a first rotating shaft 107, a guide plate 201, a pull rope 202, a cleaning roller 203, a track shell 204, a spring 205, a rope winding wheel 206, a third rotating shaft 207, a fourth bevel gear 208, a third bevel gear 209, a first guide block 210, a second guide block 211, a sliding block 213, a third port 214, a vertical plate 220, a second rotating shaft 221, a rotating support base 222, a filter plate 223, a first connecting pipe 301, a first water pump 302, a countershaft 303, a second circular gear 304, a first circular gear 305, a main shaft 306, a hub 307, a bearing base 308, a rotor 309, a second connecting pipe 310, a heat dissipation pipe, a stator 320, a first water pump 301, a first water pump 302, a second water pump, a third water pump, a third water pump, a fourth water pump, a fourth water, a third water, a fourth, The generator 321, the water stop plate 41, the heat-conducting ring 44, the condensation cone 45, the cone water receiving opening 48, the circular water stop plate 49, the fourth connecting pipe 50, the first turbine blade 431, the fifth rotating shaft 432, the swing rod 434, the scattering hammer 435, the first check valve 436, the circular housing 437, the third connecting pipe 438, the second check valve 441, the horn-shaped opening 442, the swing rod 434, the scattering hammer 435, the rainwater pipe 51, the first water filter pipe 52, the second water filter pipe 53, the condensate pipe 54, the second turbine blade 631, the fifth bevel gear 632, the sixth rotating shaft 633, the sixth bevel gear 634, the seventh rotating shaft 635, the seventh bevel gear 636, the eighth bevel gear 637, the eighth rotating shaft 638, the fourth bearing 639, the descaling spiral blade 640, the third bearing 641, the second bearing 642, the primary filter tank 71, the fifth connecting pipe 72, the filtered water storage tank 73, the condensed water storage tank 74, the sixth connecting pipe 75, the hydrogen production tank 76, the fourth connecting pipe 76, the third connecting pipe 76, the fourth connecting pipe 80, the third connecting pipe, the fourth connecting pipe, the fourth connecting pipe, the fourth connecting pipe, the fourth connecting pipe, the fourth connecting the fifth connecting the fourth connecting the fifth connecting the fourth connecting the fifth connecting the fourth connecting the fifth connecting the, A hydrogen storage tank 77, a seventh connecting pipe 78, a scale deposit tank 80, a second water pump 81, and a hydrogen production unit 82.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

As shown in fig. 1-3, the invention relates to a wind power generation rainwater collection and generator heat dissipation and hydrogen production system, which comprises a bottom box body 8, wherein a support column 5 is fixedly arranged on the upper end surface of the bottom box body 8, a support shell 9 is fixedly arranged at one end of the support column far away from the bottom box body 8, one end of the support shell 9 is rotatably connected with a fan blade group 10, and the wind power generation rainwater collection and generator heat dissipation and hydrogen production system is characterized in that: a rainwater collecting port 1 is formed in one side, away from the bottom box body 8, of the supporting shell 9, and a rainwater primary filtering and cleaning device 2 is arranged at the lower end of the rainwater collecting port 1; the power generation and heat dissipation device 3 connected with the fan blade group 10 is arranged in the supporting shell 9, and the power generation and heat dissipation device 3 is positioned in the supporting shell 9; one side of the power generation and heat dissipation device 3, which is far away from the fan blade group 10, is provided with a waterproof wall 41, a distillation generation component 4 is arranged between the waterproof wall 41 and the rainwater primary filtering and cleaning device 2, a connecting pipe group is arranged in the supporting column 5, and a rainwater storage hydrogen production component is arranged in the bottom box body 8.

As shown in fig. 3-9, the rainwater primary filtering and cleaning device 2 includes two vertical plates 220 symmetrically disposed in the supporting housing 9, a leakage-proof plate 105 is fixedly disposed on one side of the two vertical plates 220 away from the fan blade set 10, a baffle plate 103 is rotatably disposed at an upper end of one side of each vertical plate 220 facing the other vertical plate 220, a torsion spring is disposed at a rotary connection position of each baffle plate 103 and the vertical plate, and the rainwater collecting port 1 is initially closed by the baffle plate 103; a first opening is formed at the joint of each vertical plate 220 and the upper side of the leakage-proof plate 105, a first rotating shaft 107 is fixedly arranged on one side of the baffle plate 103 close to the first opening, and a first bevel gear 104 is fixedly connected to one end of the first rotating shaft 107 positioned in the first opening; a rotary support base 222 is fixedly arranged at the lower part of the first opening on one side of each vertical plate 220 facing the support shell 9, a second rotary shaft 221 extending up and down is rotatably connected in the rotary support base 222, a second bevel gear 106 is fixed at one end of the second rotary shaft 221 close to the first opening, and the first bevel gear 104 and the second bevel gear 106 are in meshing transmission; the other end of the second rotating shaft 221 is fixedly provided with a third bevel gear 209, and the third bevel gear 209 is connected with a filtering component which is arranged inside the two vertical plates 220 and is close to the bottom surface of the supporting shell 9.

As shown in fig. 3-9, the filtering assembly includes a filtering plate 223, a second opening is disposed at a lower side of the leakage-proof plate 105, the filtering plate 223 is rotatably connected to the two vertical plates 220 at the second opening, the filtering plate 223 is fixedly connected with a third rotating shaft 207, two ends of which penetrate through the two vertical plates 220, the middle portions of the rod bodies of the third rotating shaft 207, which exceed the two vertical plates 220, are respectively and fixedly connected with a fourth bevel gear 208, the fourth bevel gear 208 is in meshing transmission with a third bevel gear 209, and two ends of the third rotating shaft 207 are respectively and fixedly connected with a rope winding wheel 206; the filter 223 is close to second open-ended one end fixedly connected with slope setting and stretches out second open-ended deflector 201, filter 223 bilateral symmetry is fixed and is equipped with track casing 204, it is equipped with slider 213 to slide in every track casing 204, be connected with spring 205 between every slider 213 and the track casing 204 that corresponds the side and the length direction vertically lateral wall, every slider 213 is connected with stay cord 202 towards second open-ended one side, the stay cord 202 other end and rope winding wheel 206 fixed connection, it is connected with clearance roller 203 to rotate between two sliders 213, it is equipped with third port 214 to support casing 209 back shroud department, deflector 201 is rotatable to stretch out third port 214.

As shown in fig. 3, the power generation and heat dissipation device 3 includes a hub 307, a fan blade set 10 is fixedly connected to one side of the hub 307 extending out of the support housing 9 along an outer cylindrical surface, a bearing seat 308 is disposed on one side of the support housing 9 connecting the hub 307 and facing the generator 321, and the hub 307 and the generator 321 are connected to a main shaft 306; a first circular gear 305 is arranged on one side, close to the generator, of the middle of the main shaft 306, a first water pump 302 is arranged on the main shaft 306 in the direction towards the bottom box body 8, an auxiliary shaft 303 is connected between the water pump and the second circular gear 304, the first circular gear 305 and the second circular gear 304 are in meshed transmission, a first connecting pipe 301 is arranged on the lower side of the first water pump 302, and a second connecting pipe 310 is connected to the upper side of the water pump 302; one end of the main shaft 306 positioned in the installation shell 9 is fixedly connected with a rotor 309, the interior of the installation shell 9 is fixedly connected with a stator 320 arranged around the rotor 309, the outer circumferential surface of the stator 320 is wound with a radiating pipe 311, and a second connecting pipe 310 is connected with one end of the radiating pipe 311; the position of the water stop plate 41 opposite to the rotor 309 is provided with a fourth opening, one side of the rotor 309 facing the water stop plate 41 is fixedly connected with a heat conduction ring 44, the middle part of the heat conduction ring is provided with a circular water stop plate 49, the other end of the heat dissipation pipe 311 extends out of the water stop plate 41, one end of the heat dissipation pipe 311 extending out of the circular shell 437 is fixedly connected with a circular shell 437, one end of the heat dissipation pipe 311 connected with the circular shell 437 is provided with a first check valve 436, a fifth rotating shaft 432 is rotatably arranged in the circular shell 437, the fifth rotating shaft 432 is provided with a plurality of first turbine blades 431 which are uniformly distributed, the circular shell 437 is located at the upper side position of the heat conduction ring 44, the lower side of the circular shell 437 is provided with a plurality of water sprinkling assemblies, the circular shell is provided with a third connecting pipe 438 facing one side of the fan blade group 10, and a second check valve 441 is arranged in the third connecting pipe 438.

As shown in fig. 3 and 4, the sprinkler assembly includes a trumpet-shaped opening 442 fixedly disposed on one side of the circular housing 437 facing the heat-conducting circular ring 44, the trumpet-shaped opening 442 is communicated with the inside of the circular housing 437, a swing rod 434 is rotatably connected in the trumpet-shaped opening 442, a scattering hammer 435 is fixedly connected to one side of the swing rod 434 facing the heat-conducting circular ring 44, and a torsion spring is disposed at a rotational connection position of the swing rod 434 and the trumpet-shaped opening 442.

As shown in fig. 3, the distillation generating component 4 includes an inverted triangular condensation cone 45 fixedly disposed on the mounting housing 9 and located at the upper side of the heat conducting ring 44, a conical water receiving opening 48 is disposed at the lower side of the gravity center position of the condensation cone 45, and a fourth connecting pipe 50 is communicated with the lower side of the conical water receiving opening 48.

As shown in fig. 3, the rainwater storage hydrogen production component includes a primary filter tank 71 arranged inside the bottom tank 8, a filtered water storage tank 73 is arranged at the lower side of the primary filter tank 71, the filtered water storage tank 73 and the primary filter tank 71 are connected to a fifth connecting pipe 72, a condensed water storage tank 74 is arranged at the lower side of the filtered water storage tank 73, a second water pump 81 is arranged at the bottom of the condensed water storage tank 74, a sixth connecting pipe 75 is connected to the second water pump 81 in the direction towards the hydrogen production tank, the other end of the sixth connecting pipe 75 is connected to the hydrogen production tank 76, a hydrogen production component 82 is arranged at the bottom of the hydrogen production tank 76, and an exhaust pipe is arranged at the position of the hydrogen production component 82 towards the outer side of the bottom tank 8; a hydrogen storage tank 77 is provided on the upper side of the hydrogen production tank 76, and a seventh connecting pipe 78 is connected to the hydrogen storage tank 77 and the hydrogen production tank 76.

As shown in fig. 3, the scale removing member includes a rain pipe 51 inside the supporting column 5, a plurality of second turbine blades 631 are disposed inside an end of the rain pipe 51 connected to the primary filter tank 71, the second turbine blades 631 are uniformly distributed on an outer circumferential surface of the sixth rotating shaft 633, the sixth rotating shaft 633 is extended toward the primary filter tank 71 and connected to a second bearing base 642, the bearing base 642 is disposed on the primary filter tank 71 toward the hydrogen storage tank 77, and the sixth rotating shaft 633 is extended toward the hydrogen storage tank 77 and connected to a fifth bevel gear 632; the bottom of the bottom box 8 is provided with a third bearing seat 641, the upper side of the third bearing seat 641 is connected with a seventh rotating shaft 635, the upper side of the seventh rotating shaft 635 is provided with a sixth bevel gear 634, the sixth bevel gear 634 is in meshing transmission with a fifth bevel gear 632, a seventh bevel gear 636 is arranged on the seventh rotating shaft 635 between the sixth bevel gear 634 and the third bearing seat 641, the seventh bevel gear 636 is arranged between the sixth bevel gear 634 and the third bearing seat 641, the seventh bevel gear 636 is provided with an eighth bevel gear 637 facing the direction of the water filtering storage box 73, the seventh bevel gear 636 is in meshing transmission with the eighth bevel gear 637, the eighth bevel gear 637 is provided with an eighth rotating shaft 638 facing the direction of the water filtering storage box 73, and the joint of the eighth rotating shaft 638 and the water filtering storage box 73 is provided with a fourth bearing seat 639; the eighth rotating shaft 638 extends towards the water filtering storage tank 73 to be connected with the outer side wall of the water filtering storage tank 73, the eighth rotating shaft 638 is provided with a descaling helical blade 640 on the circumferential surface in the water filtering storage tank 73, and the water filtering storage tank 73 is provided with a scale deposit box 80 towards the side wall direction of the bottom box 8.

As shown in fig. 5 and 3, the support column 5 is provided with a rainwater pipe 51 with a half volume, the upper side of the rainwater pipe 51 is communicated with the lower part of the filtering assembly, and the lower side of the rainwater pipe 51 is connected with one surface of the primary filtering tank 71 facing the hydrogen storage tank 77; a condensate pipe 54 is arranged at the center of the support column 5, the upper side of the condensate pipe 54 is connected with one end of the fourth connecting pipe 50, and the lower side of the condensate pipe 54 is connected with a condensate water storage tank 74 towards the direction of the hydrogen production tank 76; the support column 5 is provided with a first water filter pipe 52, the upper side of the first water filter pipe 52 is connected with one end of a first connecting pipe 301, and the lower side of the first water filter pipe 52 is communicated with a water filter storage tank 73 towards the hydrogen production tank 76; the support column 5 is provided with a second water filter pipe 53, the upper side of the second water filter pipe 53 is connected with one end of a third connecting pipe 438, and a water filtering storage tank 73 at the lower side of the second water filter pipe 53 is communicated towards the hydrogen production tank 76.

The working principle of the invention is as follows:

firstly, the fan blade set 10 is driven by wind power to rotate, the main shaft 306 is driven by the fan blade set 10 to start rotating, the rotor 309 also rotates after the main shaft 306 rotates, so that the generator 321 starts to work, and simultaneously, the first circular gear 305 on the main shaft 306 also starts to rotate, so that the first water pump 302 starts to work, filtered water flows from the filtered water storage tank 73 to the radiating pipe 311, so that the generator 321 is radiated;

further, when the filtered water flows to the sprinkler assembly after being radiated by the radiating pipe 311 around the generator 321 for one circle, the connection between the sprinkler assembly and the radiating pipe 311 is provided with the first check valve 436 to prevent the water from flowing backward, the water rotates the first turbine blade 431 in the sprinkler assembly, the first turbine blade 431 swings the swing lever 434 when the water flows to the bell-shaped opening 442, the swing lever 434 swings the scattering hammer 435, so that the water is in a form of small water drops when the water is sprayed onto the surface of the heat conducting ring 44 through the bell-shaped opening 442, the surface temperature of the rotor 309 rotating in connection with the heat conducting ring 44 is higher, so that the water sprayed onto the surface of the heat conducting ring 44 is evaporated, and the water vapor is collected at the condensation cone 45 at the upper portion of the sprinkler assembly to form condensed water and flows to the condensed water storage tank 74 through the cone water receiving opening 48, and at this time, the water inside the sprinkler assembly flows to the filtered water storage tank 73 through the third connecting pipe 438, a second one-way valve 441 is arranged at the joint of the third connecting pipe 438 and the sprinkling assembly to prevent water from flowing backwards;

when raining, the inclined collecting plate 101 is inclined to optimize the rainwater collecting amount, and at the same time, the two baffle plates 103 are driven by the gravitational potential energy of rainwater to rotate the baffle plates 103 and the first rotating shaft 107 downwards to form an opening to collect rainwater, when the first rotating shaft 107 rotates downwards to drive the first bevel gear 104 to rotate, so as to drive the second bevel gear 106 in meshing transmission with the first bevel gear 104 to rotate, so as to drive the second rotating shaft 221 to rotate, so as to drive the third bevel gear 209 to rotate, so as to drive the fourth bevel gear 208 in meshing transmission with the third bevel gear 209 to rotate, so as to drive the third rotating shaft 207 to rotate, so as to drive the rope winding wheel 206 to rotate, and when the rope winding wheel 206 rotates to release the rope 202, so that the spring 205 pulls the sliding block 213 towards the first guiding block 210 direction, so as to drive the cleaning roller 203 to move towards the first guiding block 210 direction, so as to make the cleaning roller 203 be located at the side of the filtering plate 223 close to the first guiding block 210, meanwhile, the third rotating shaft 207 rotates to drive the filter plate 223 to rotate downwards until the filter plate is horizontal, and at the moment, the guide plate 201 rotates upwards to shield the third through port 214, so that rainwater cannot flow out of the supporting shell 9, and when the rainwater flows to the filter plate 223 through the first guide block 210, the rainwater flows through the filter plate 223 and flows to the rainwater pipe 51 through the second guide block 211, and when the rainwater is filtered, waste is left on the filter plate 223;

further, when there is no rain, the two baffles 103 are lifted upwards, so as to close and prevent the waste from falling into the tax collecting and collecting unit when there is no rain, and when the first rotating shaft 107 is rotated reversely to the rain, so that the driving unit is rotated reversely, so as to lift the filter plate 223 upwards, so that the cleaning roller 203 moves towards the third through opening 214, the filtered waste will be pushed out of the supporting housing 9 by the cleaning roller 203 for the purpose of cleaning the filtered waste;

meanwhile, when rainwater flows to the primary filter tank 71 through the rainwater pipe 51, rainwater potential energy drives the second turbine blade 631 to rotate, so as to drive the sixth rotating shaft 633 to rotate, so as to drive the fifth bevel gear 632 to rotate, so as to drive the sixth bevel gear 634 in meshing transmission with the fifth bevel gear 632 to rotate, so as to drive the seventh rotating shaft 635 to rotate, so as to drive the seventh bevel gear 636, so as to drive the eighth bevel gear 637 in meshing transmission with the seventh bevel gear 636 to rotate, so as to drive the eighth rotating shaft 638 to rotate, so as to drive the descaling helical blade 640 to rotate, so that the descaling helical blade 640 scrapes scale generated by heat of heat-dissipating water in the filtered water tank 73, and when the descaling helical blade 640 pushes the scale to the scale accumulation tank 80, a maintainer only needs to regularly collect and treat the scale from the scale accumulation tank 80, so as to improve the practicability of the invention;

when the generator is in a power generation peak period, the hydrogen production assembly starts to work, firstly, the second water pump 81 conveys condensed water from the condensed water storage tank 74 to the hydrogen production tank 76, so that the hydrogen production component 82 in the hydrogen production tank works by using the condensed water, the produced hydrogen is conveyed to 77 the hydrogen storage tank through the seventh connecting pipe 78 for storage, oxygen is discharged through the exhaust pipe, and the hydrogen production component 82, the first water pump 302 and the second water pump 81 are the prior art and are not described herein.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides a wind power generation rainwater is collected and generator heat dissipation and hydrogen manufacturing system, includes bottom box (8), the fixed support column (5) that is equipped with of up end of bottom box (8), the fixed support housing (9) that is equipped with of one end that bottom box (8) were kept away from to the support column, the one end of support housing (9) is rotated and is connected with fan blade group (10), its characterized in that: a rainwater collecting port (1) is formed in one side, away from the bottom box body (8), of the supporting shell (9), and a rainwater primary filtering and cleaning device (2) is arranged at the lower end of the rainwater collecting port (1); the power generation and heat dissipation device (3) connected with the fan blade group (10) is arranged in the supporting shell (9), and the power generation and heat dissipation device (3) is positioned in the supporting shell (9); one side that fan blade group (10) was kept away from in electricity generation heat abstractor (3) is equipped with bulkhead (41), be equipped with distillation emergence part (4) between bulkhead (41) and rainwater prefiltration and cleaning device (2), be equipped with the connecting tube group in support column (5), be equipped with the rainwater in bottom box (8) and store hydrogen manufacturing and scale removal part.

2. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system of claim 1, wherein: the rainwater is collected the outside upper end of mouth (1) and is provided with tilting collection board (101), the rainwater is collected mouth (1) and is equipped with first guide block (210) near the part downside of flabellum group (10), one side that supporting shell (9) diapire was kept away from flabellum group (10) is equipped with second guide block (211) of slope direction support column (5).

3. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system of claim 2, wherein: the rainwater primary filtering and cleaning device (2) comprises two vertical plates (220) symmetrically arranged in a supporting shell (9), a leakage-proof plate (105) is fixedly arranged on one side, away from a fan blade group (10), of the two vertical plates (220), a baffle (103) is rotatably arranged at the upper end of one side, facing the other vertical plate (220), of each vertical plate (220), a torsion spring is arranged at the rotary connection position of each baffle (103) and the corresponding vertical plate, and the rainwater collecting port (1) is initially closed by the baffles (103); a first opening is formed in the joint of each vertical plate (220) and the upper side of the leakage-proof plate (105), a first rotating shaft (107) is fixedly arranged on one side, close to the first opening, of the baffle plate (103), and a first bevel gear (104) is fixedly connected to one end, located in the first opening, of the first rotating shaft (107); a rotating support base (222) is fixedly arranged at the lower part of the first opening on one side of each vertical plate (220) facing the support shell (9), a second rotating shaft (221) extending up and down is rotatably connected to the rotating support base (222), a second bevel gear (106) is fixedly arranged at one end, close to the first opening, of the second rotating shaft (221), and the first bevel gear (104) and the second bevel gear (106) are in meshing transmission; the other end of the second rotating shaft (221) is fixedly provided with a third bevel gear (209), and the third bevel gear (209) is connected with a filtering component which is arranged inside the two vertical plates (220) and is close to the bottom surface of the supporting shell (9).

4. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system of claim 3, wherein: the filter assembly comprises a filter plate (223), a second opening is formed in the lower side of the leakage-proof plate (105), the filter plate (223) is rotatably connected to the two vertical plates (220) at the position of the second opening, the filter plate (223) is fixedly connected with a third rotating shaft (207) of which two ends penetrate through the two vertical plates (220), the middle parts of rod bodies of the third rotating shaft (207) exceeding the two vertical plates (220) are respectively and fixedly connected with a fourth bevel gear (208), the fourth bevel gear (208) is in meshing transmission with the third bevel gear (209), and two ends of the third rotating shaft (207) are respectively and fixedly connected with a rope winding wheel (206); the filter (223) are close to second open-ended one end fixedly connected with slope and set up and stretch out second open-ended deflector (201), filter (223) bilateral symmetry is fixed and is equipped with track casing (204), every slide in track casing (204) and be equipped with slider (213), every slider (213) and the track casing (204) that corresponds the side with length direction vertically between the lateral wall be connected with spring (205), every slider (213) are connected with stay cord (202) towards second open-ended one side, stay cord (202) other end and rope winding wheel (206) fixed connection, two it is connected with clearance roller (203) to rotate between slider (213), it is equipped with third opening (214) to support casing (209) back shroud department, deflector (201) rotatable third opening (214) of stretching out.

5. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system of claim 1, wherein: the power generation and heat dissipation device (3) comprises a hub (307), one side, extending out of a support shell (9), of the hub (307) is fixedly connected with a fan blade group (10) along an outer cylindrical surface, a bearing seat (308) is arranged on one side, facing a generator (321), of the support shell (9) connected with the hub (307), and the hub (307) and the generator (321) are connected with a main shaft (306); a first circular gear (305) is arranged on one side, close to the generator, of the middle of the main shaft (306), a first water suction pump (302) is arranged on the main shaft (306) in the direction towards the bottom box body (8), an auxiliary shaft (303) is connected between the water suction pump and the second circular gear (304), the first circular gear (305) and the second circular gear (304) are in meshed transmission, a first connecting pipe (301) is arranged on the lower side of the first water suction pump (302), and a second connecting pipe (310) is connected to the upper side of the water suction pump (302); one end, located in the installation shell (9), of the spindle (306) is fixedly connected with a rotor (309), a stator (320) arranged around the rotor (309) is fixedly connected inside the installation shell (9), the outer circumferential surface of the stator (320) is wound with a radiating pipe (311), and the second connecting pipe (310) is connected with one end of the radiating pipe (311); the water stop plate (41) and the rotor (309) are opposite to each other and provided with a fourth opening, one side of the rotor (309) facing the water stop plate (41) is fixedly connected with a heat conduction ring (44), the middle part of the heat conduction ring is provided with a circular water stop plate (49), the other end of the heat dissipation pipe (311) extends out of the water stop plate (41), one end of the heat dissipation pipe (311) extending out of the water stop plate (41) is fixedly connected with a circular shell (437), one end of the heat dissipation pipe (311) connected with the circular shell (437) is provided with a first check valve (436), a fifth rotating shaft (432) is rotatably arranged in the circular shell (437), the fifth rotating shaft (432) is provided with a plurality of first turbine blades (431) which are uniformly distributed, the circular shell (437) is positioned at the upper side of the heat conduction ring (44), and a plurality of water sprinkling assemblies are arranged at the lower side of the circular shell (437), a third connecting pipe (438) is arranged on one side, facing the fan blade group (10), of the circular shell, and a second one-way valve (441) is arranged in the third connecting pipe (438).

6. The wind-powered rainwater collection and generator heat dissipation and hydrogen production system of claim 5, wherein: the watering subassembly is including fixed horn shape opening (442) that sets up towards heat conduction ring (44) one side in circular casing (437), horn shape opening (442) link up with circular casing (437) are inside, horn shape opening (442) internal rotation is connected with pendulum rod (434), pendulum rod (434) break up hammer (435) towards one side fixedly connected with of heat conduction ring (44), pendulum rod (434) rotate the junction with horn shape opening (442) and are equipped with the torsional spring.

7. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system according to claim 6, wherein: distillation emergence part (4) are including fixed setting up in installation casing (9) be located heat conduction ring (44) upside position inverted triangle's condensation awl (45), condensation awl (45) focus position downside is provided with toper water receiving mouth (48), toper water receiving mouth (48) downside intercommunication has fourth connecting pipe (50).

8. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system of claim 7, wherein: the rainwater storage hydrogen production part comprises a primary filter tank (71) arranged inside a bottom tank body (8), a filtered water storage tank (73) is arranged on the lower side of the primary filter tank (71), the filtered water storage tank (73) and the primary filter tank (71) are connected to a fifth connecting pipe (72), a condensed water storage tank (74) is arranged on the lower side of the filtered water storage tank (73), a second water suction pump (81) is arranged at the bottom of the condensed water storage tank (74), the second water suction pump (81) is connected with a sixth connecting pipe (75) towards the hydrogen production tank, the other end of the sixth connecting pipe (75) is connected with a hydrogen production tank (76), a hydrogen production part (82) is arranged at the bottom of the hydrogen production tank (76), and an exhaust pipe is arranged on the hydrogen production part (82) towards the outer side of the bottom tank body (8); the hydrogen production tank (76) is provided with a hydrogen storage tank (77) on the upper side, and the hydrogen storage tank (77) and the hydrogen production tank (76) are connected with a seventh connecting pipe (78).

9. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system of claim 8, wherein: the scale removing component comprises a rainwater pipe (51) inside a supporting column (5), a plurality of second turbine blades (631) are arranged inside one end, connected with a primary filter box (71), of the rainwater pipe (51), the second turbine blades (631) are uniformly distributed on the outer circumferential surface of a sixth rotating shaft (633), the sixth rotating shaft (633) extends towards one side of the primary filter box (71) and is connected with a second bearing seat (642), the bearing seat (642) is arranged on one side, facing a hydrogen storage box (77), of the primary filter box (71), and the sixth rotating shaft (633) extends towards one side of the hydrogen storage box (77) and is connected with a fifth bevel gear (632); a third bearing seat (641) is arranged at the bottom of the bottom box body (8), a seventh rotating shaft (635) is connected to the upper side of the third bearing seat (641), a sixth bevel gear (634) is arranged on the upper side of the seventh rotating shaft (635), the sixth bevel gear (634) is in meshing transmission with a fifth bevel gear (632), a seventh bevel gear (636) is arranged between the sixth bevel gear (634) and the third bearing seat (641) and on the seventh rotating shaft (635), the seventh bevel gear (636) is arranged between the sixth bevel gear (634) and the third bearing seat (641), an eighth bevel gear (637) is arranged in the direction of the water filtering storage box (73) by the seventh bevel gear (636), the seventh bevel gear (636) is in meshing transmission with the eighth bevel gear (637), and an eighth rotating shaft (638) is arranged in the direction of the water filtering storage box (73) by the eighth bevel gear (637), a fourth bearing seat (639) is arranged at the joint of the eighth rotating shaft (638) and the water filtering storage box (73); eighth axis of rotation (638) stretches out towards drainage storage tank (73) and is connected with drainage storage tank (73) lateral wall, the circumference surface of eighth axis of rotation (638) in drainage storage tank (73) is provided with scale removal helical blade (640), drainage storage tank (73) is provided with incrustation scale accumulation case (80) towards bottom box (8) lateral wall direction.

10. The wind power generation rainwater collection and generator heat dissipation and hydrogen production system of claim 9, wherein: the support column (5) is provided with a rainwater pipe (51) with half volume, the upper side of the rainwater pipe (51) is communicated with the lower part of the filtering component, and the lower side of the rainwater pipe (51) is connected with one surface of the primary filtering box (71) facing the direction of the hydrogen storage box (77); a condensate pipe (54) is arranged in the center of the supporting column (5), the upper side of the condensate pipe (54) is connected with one end of a fourth connecting pipe (50), and the lower side of the condensate pipe (54) is connected with a condensate water storage tank (74) towards the hydrogen production tank (76); the support column (5) is provided with a first water filter pipe (52), the upper side of the first water filter pipe (52) is connected with one end of a first connecting pipe (301), and the lower side of the first water filter pipe (52) is communicated with a water filter storage tank (73) towards the direction of the hydrogen production tank (76); the support column (5) is provided with a second water filter pipe (53), the upper side of the second water filter pipe (53) is connected with one end of a third connecting pipe (438), and a water filter storage tank (73) on the lower side of the second water filter pipe (53) is communicated towards the direction of the hydrogen production tank (76).