CN116022941A

CN116022941A - Wind-solar complementary new energy water oxygen supply system

Info

Publication number: CN116022941A
Application number: CN202310113419.7A
Authority: CN
Inventors: 王栋
Original assignee: Guangdong Yongguang New Energy Design Consulting Co ltd
Current assignee: Guangdong Yongguang New Energy Design Consulting Co ltd
Priority date: 2023-02-11
Filing date: 2023-02-11
Publication date: 2023-04-28
Anticipated expiration: 2043-02-11
Also published as: CN116022941B

Abstract

The application relates to a wind-solar complementary new energy water body oxygen supply system, which comprises a floating island, a wind-solar complementary new energy water body oxygen supply system and a wind-solar complementary new energy water body oxygen supply system, wherein the floating island floats in a water body; the support rod is fixedly connected to the upper surface of the floating island; the photovoltaic power generation system is connected with the supporting rod and used for generating electric energy; the wind power generation system is connected with the supporting rod and used for generating electric energy; the storage battery is connected with the floating island and used for storing electric energy generated by the photovoltaic power generation system and the wind power generation system; the aerator is connected with the storage battery and is used for aerating the water body; the blast pipe is connected with the oxygen-increasing machine, and the remaining one end of blast pipe is pegged graft to in the aquatic, and this application has the effect of being convenient for carry out comprehensive oxygen suppliment to the waters of different occasions.

Description

Wind-solar complementary new energy water oxygen supply system

Technical Field

The application relates to the technical field of new energy oxygen supply systems, in particular to a wind-solar complementary new energy water body oxygen supply system.

Background

The wind-solar complementary new energy system is a set of power generation application system, the system stores generated electric energy into a storage battery by utilizing a solar cell policy and a wind driven generator, and when a user needs to use electricity, an inverter converts direct current stored in the storage battery into alternating current; and the power is transmitted to a load through a power transmission line. The wind-solar complementary new energy water body oxygen supply system is used for supplying power to oxygen supply equipment by using generated electric energy.

The prior Chinese patent with reference to publication number CN210248011U discloses an oxygen supply device for a wind-solar complementary new energy pool; including photovoltaic power generation system and wind power generation system, still include: the support columns are fixed on the periphery of the pool, and support seats are installed and fixed at the tops of the support columns; the sliding seat is connected to the supporting seat in a sliding way, and a screw rod is rotationally connected to the supporting seat; the fixing plate is used for fixing the wind driven generator, a first fixing rod is fixed at the bottom of the fixing plate, the end part of the first fixing rod is connected with a second fixing rod, and the end part of the second fixing rod is rotationally connected in the sliding seat through a bearing; the photovoltaic panel is fixedly arranged at the end part of the second support rod; the wind-solar complementary new energy pool oxygen supply device adopts a photovoltaic power generation system and a wind power generation system to supply power for an oxygen supply water pump.

In the related art, when oxygen supply is required to be performed to a water area with a large area and an aeration device is inconvenient to be laid below the water area, there is a defect that the oxygen supply to the water area cannot be uniformly and comprehensively performed.

Disclosure of Invention

In order to solve the defect that comprehensive oxygen supply cannot be performed on a water area, the application provides a wind-solar complementary new energy water body oxygen supply system.

The application provides a wind-solar complementary new energy water body oxygen supply system, which adopts the following technical scheme: a floating island floating on the water body; the support rod is fixedly connected to the upper surface of the floating island; the photovoltaic power generation system is connected with the supporting rod and used for generating electric energy; the wind power generation system is connected with the supporting rod and used for generating electric energy; the storage battery is connected with the floating island and used for storing electric energy generated by the photovoltaic power generation system and the wind power generation system; the aerator is connected with the storage battery and is used for aerating the water body; and the exhaust pipe is connected with the aerator, and the remaining end of the exhaust pipe is spliced into the water body.

By adopting the technical scheme, the floating island is placed in the water body to be supplied with oxygen when in use, at the moment, the photovoltaic power generation system converts light energy into electric energy, and meanwhile, the wind power generation system converts wind energy into electric energy; the storage battery is used for storing electric energy generated by the wind power generation system and the photovoltaic power generation system and supplying power for the aerator, and the aerator pumps oxygen-containing gas into the water body through the exhaust pipe so as to increase the oxygen content in the water body; the floating island can realize oxygen supply to the water area with larger area and uneven pool bottom, which is inconvenient for paving the aeration pipe; meanwhile, the floating island is convenient for supplying oxygen to different positions in the water area.

Preferably, one end of the exhaust pipe, which is away from the aerator, is connected with an air disc.

Through adopting above-mentioned technical scheme, the setting of gas dish has increased the quantity of venthole, has reduced the volume of bubble, has slowed down the bubble and has risen the speed, and then has increased the oxygen content of water.

Preferably, the air disk is connected with a turbulence tube, and the turbulence tube is fixedly connected to one side of the air disk, which is not provided with the air outlet hole; and the turbulence barrel gradually forms a tip shape from one side close to the air disk to one side away from the air disk.

Through adopting above-mentioned technical scheme, the vortex section of thick bamboo has reduced and has produced resistance between gas dish and the water when removing, simultaneously when the floating island drive gas dish moves forward, because the vortex section of thick bamboo has the function of reposition of redundant personnel, for this, the rivers can strike the gas dish in the removal in-process, and then improve the travel speed.

Preferably, the floating island top is connected with the material piece of throwing, throws the material piece and includes: the storage box is fixedly connected to the upper surface of the floating island and is used for storing materials; the rotating shaft penetrates through the storage box and is rotationally connected with the storage box; the feeding spoon is fixedly connected to the circumferential direction of the rotating shaft and is used for throwing materials in the storage box; the supporting rod is connected with a stop piece for stopping the feeding spoon; the exhaust pipe is communicated with a power piece for driving the rotating shaft to rotate.

By adopting the technical scheme, when oxygen is supplied to the water body, the feeding part feeds materials into the water body, wherein the materials can be water body purifying agents or foodstuff and the like; when the material throwing device is used, the power piece drives the rotating shaft to rotate, and meanwhile, the rotating shaft drives the material throwing spoon to rotate, so that the material in the material storage box is dug out by the material throwing spoon, and the material is thrown under the stop effect of the stop piece; when the oxygen supply system is used for cultivation, oxygen content around the floating island is high when the water body is fed, so that aerobic organisms can gather around the floating island, and foodstuff is thrown at the moment, and the utilization rate of the foodstuff is improved.

Preferably, the power member includes: the installation shell is fixedly connected and communicated with the exhaust pipe; the impeller, part of the impeller is located in the mounting shell, and the flabellum of the impeller is located in the exhaust pipe; the transmission shaft penetrates through the mounting shell and is rotationally connected with the mounting shell, and the transmission shaft is coaxially and fixedly connected with the impeller; the connecting shaft is connected with the rotating shaft and the transmission shaft; the first bevel gear set is used for connecting the rotating shaft and the connecting shaft; and the second bevel gear set is used for connecting the transmission shaft and the connecting shaft.

By adopting the technical scheme, when oxygen is supplied to a water body, high-speed air flow exists in the exhaust pipe, the air flow drives the impeller to rotate so as to drive the transmission shaft to rotate, the transmission shaft drives the connecting shaft to rotate under the action of the second bevel gear set, and the connecting shaft drives the rotating shaft to rotate under the action of the first bevel gear set so as to drive the feeding spoon to rotate, so that the feeding of materials is realized; the feeding of the aerobe is realized while oxygen is supplied, and the utilization rate of the foodstuff is improved.

Preferably, the stop piece comprises a stop rod and a stop spring, the stop rod is positioned above the storage box, and the stop rod is used for stopping the feeding spoon; the stop spring is connected with the stop rod and the support rod.

By adopting the technical scheme, when the material throwing spoon contacts the stop rod, the stop rod stops the material throwing spoon, and at the moment, the material is thrown into water under the inertia effect; along with the continuous rotation of the rotating shaft, the stop spring deforms, and the feeding spoon continuously rotates at the moment, so that the material is thrown.

Preferably, the storage box is fixedly connected with two stop plates, the two stop plates are parallel to each other, and the stop plates are perpendicular to the rotating shaft; a discharging hole is formed in one side of the stop plate, which is close to the lower part of the storage box.

Through adopting above-mentioned technical scheme, the setting of backstop board has reduced the contact of the spoon handle of throwing the material spoon and material, and then has reduced the resistance that the material spoon received.

Preferably, a sleeve is arranged between the side wall of the two stop plates, which is away from each other, and the inner wall of the storage box, and the sleeve is fixedly connected with the storage box; the rotating shaft is sleeved in the sleeve, and the diameter of the section of the rotating shaft is smaller than the inner diameter of the sleeve.

Through adopting above-mentioned technical scheme, sheathed tube setting has reduced the friction that produces between material in the storage box probably and the pivot, and then is convenient for the pivot to rotate.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the floating island can realize oxygen supply to the water area with larger area and uneven pool bottom, which is inconvenient for paving the aeration pipe; meanwhile, the floating island is arranged so as to be convenient for supplying oxygen to different positions in the water area;

2. when oxygen is supplied to the water body, high air flow exists in the exhaust pipe, the air flow drives the impeller to rotate so as to drive the transmission shaft to rotate, the transmission shaft drives the connecting shaft to rotate under the action of the second bevel gear set, and the connecting shaft drives the rotating shaft to rotate under the action of the first bevel gear set so as to drive the feeding spoon to rotate, so that the feeding of materials is realized; feeding of aerobe is realized while oxygen is supplied, and the utilization rate of foodstuff is improved;

3. the setting of the stop plate reduces the contact between the spoon handle of the feeding spoon and the material, and further reduces the resistance of the feeding spoon.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present application;

FIG. 2 is a cross-sectional view showing an aerator;

FIG. 3 is a cross-sectional view showing an impeller;

fig. 4 is a sectional view showing the sleeve.

In the figure, 1, a floating island; 2. a support rod; 3. a photovoltaic power generation system; 4. a wind power generation system; 5. a storage battery; 6. an aerator; 61. an exhaust pipe; 7. an air tray; 71. a turbulence tube; 8. a feeding part; 81. a storage bin; 811. a stop plate; 812. a discharge hole; 813. a sleeve; 82. a rotating shaft; 83. a feeding spoon; 9. a power member; 91. a mounting shell; 92. an impeller; 93. a transmission shaft; 94. a connecting shaft; 95. a first bevel gear set; 96. a second bevel gear set; 10. a stopper; 101. a stop lever; 102. and a stop spring.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-4.

The embodiment of the application discloses a wind-solar complementary new energy water body oxygen supply system.

Referring to fig. 1 and 2, the wind-solar complementary new energy water body oxygen supply system comprises a floating island 1, a supporting rod 2, a photovoltaic power generation system 3, a wind power generation system 4, a storage battery 5, an aerator 6 and an exhaust pipe 61; the floating island 1 floats on a water body, and the supporting rod 2 is fixedly connected to the upper surface of the floating island 1; the photovoltaic power generation system 3 and the wind power generation system 4 are fixedly connected with the supporting rod 2, and the photovoltaic power generation system 3 and the wind power generation system 4 are used for generating electric energy, and the generated electric energy is stored in the storage battery 5; the storage battery 5 is fixedly connected in the floating island 1, the storage battery 5 is connected with the aerator 6 and is used for supplying power to the aerator 6, the aerator 6 is used for aerating water, the exhaust pipe 61 is connected with the aerator 6, and the remaining end of the exhaust pipe 61 is inserted into the water.

Referring to fig. 1 and 2, specifically, one end of the exhaust pipe 61 facing away from the aerator 6 is connected with an air disc 7, the air disc 7 is of a tubular structure with two closed ends, and one end face of the air disc 7 is provided with a plurality of air outlet holes; in the present embodiment, the exhaust pipe 61 penetrates the circumferential side wall of the air tray 7 and is connected to the air tray 7; the side wall of the air disc 7, which is not provided with an air outlet hole, is fixedly connected with a turbulence barrel 71, and the turbulence barrel 71 gradually forms a tip shape from one side close to the air disc 7 to one side away from the air disc 7.

When the floating island is used, the floating island 1 is placed in the water body to be supplied with oxygen, at the moment, the photovoltaic power generation system 3 converts light energy into electric energy, and meanwhile, the wind power generation system 4 converts wind energy into electric energy; the storage battery 5 is used for storing electric energy generated by the wind power generation system 4 and the photovoltaic power generation system 3 and supplying power to the aerator 6, and the aerator 6 pumps oxygen-containing gas into the water body through the exhaust pipe 61 so as to increase the oxygen content in the water body; the floating island 1 can supply oxygen to a water area with a larger area and uneven pool bottom, which is inconvenient for paving an aeration pipe; meanwhile, the floating island 1 is arranged to be convenient for supplying oxygen to different positions in the water.

Referring to fig. 2 and 4, a feeding part 8 is connected above the floating island 1, the feeding part 8 comprises a storage box 81, a rotating shaft 82 and a feeding spoon 83, and the storage box 81 is fixedly connected to the upper surface of the floating island 1 for storing materials; the rotating shaft 82 penetrates through the storage box 81 and is rotationally connected with the storage box 81; the material throwing spoon 83 is fixedly connected to the circumference of the rotating shaft 82, and the material throwing spoon 83 is used for throwing materials in the material storage box 81. The supporting rod 2 is connected with a stop piece 10 for stopping the feeding spoon 83, and the exhaust pipe 61 is communicated with a power piece 9 for driving the rotating shaft 82 to rotate. A stop plate 811 is arranged in the storage box 81, two stop plates 811 are arranged, the two stop plates 811 are parallel to each other, and the stop plates 811 are perpendicular to the rotating shaft 82; a discharging hole 812 is formed in one side of the stop plate 811, which is close to the lower side of the storage box 81; the outlet 812 is used to flow the material in the storage bin 81 between the two stop plates 811. A sleeve 813 is arranged between the side wall of the two stop plates 811, which are away from each other, and the inner wall of the storage box 81, and the sleeve 813 is fixedly connected with the storage box 81; the rotating shaft 82 is sleeved in the sleeve 813, and the diameter of the section of the rotating shaft 82 is smaller than the inner diameter of the sleeve 813.

Referring to fig. 2 and 3, a specific power member 9 includes: a mounting case 91, an impeller 92, a transmission shaft 93, a connection shaft 94, a first bevel gear set 95, and a second bevel gear set 96; the installation shell 91 is fixedly connected and communicated with the exhaust pipe 61, a part of impellers 92 are positioned in the installation shell 91, and the blades of the impellers 92 are positioned in the exhaust pipe 61; the transmission shaft 93 penetrates through the mounting shell 91 and is rotatably connected with the mounting shell 91; and the transmission shaft 93 is fixedly connected with the impeller 92 coaxially; the connecting shaft 94 is used for connecting the rotating shaft 82 and the transmission shaft 93, and a specific first bevel gear set 95 is used for connecting the rotating shaft 82 and the connecting shaft 94; a second bevel gear set 96 is used to connect the drive shaft 93 and the connecting shaft 94.

Referring to fig. 1 and 4, the specific stopper 10 includes a stopper rod 101 and a stopper spring 102, the stopper rod 101 being located above the storage tank 81, and the stopper rod 101 being for stopping the ladle 83, the stopper spring 102 connecting the stopper rod 101 and the support rod 2.

When in use, the aerator 6 is started, and the aerator 6 blows gas into the exhaust pipe 61; at this time, the gas drives the impeller 92 to rotate, under the action of the impeller 92, the transmission shaft 93 rotates under the action of the second bevel gear set 96, the connecting shaft 94 rotates, under the action of the first bevel gear set 95, the first bevel gear set 95 drives the rotating shaft 82 to rotate, and the rotating shaft 82 rotates to drive the feeding spoon 83 to rotate; at this time, the material in the storage box 81 flows from the discharging hole 812 to the position between the two stop plates 811; the material throwing spoon 83 is used for containing materials and driving the materials to rotate, when the material throwing spoon 83 contacts the stop rod 101, the material throwing spoon 83 stops, the materials are thrown into water, the impeller 92 continues to rotate, the stop spring 102 deforms at the moment, and the material throwing spoon 83 continues to rotate; the material is thrown once. When the impeller 92 rotates, the oxygen content in the water is high, and the oxygen in the water is sufficient; the aerobic organisms gather around the floating island 1, and at the moment, the feeding part 8 feeds materials, so that the utilization rate of the materials is improved.

The implementation principle of the wind-solar complementary new energy water body oxygen supply system provided by the embodiment of the application is as follows: the floating island 1 can supply oxygen to a water area with a larger area and uneven pool bottom, which is inconvenient for paving an aeration pipe; meanwhile, the floating island 1 is arranged to be convenient for supplying oxygen to different positions in the water area; when oxygen is supplied, the gas in the exhaust pipe 61 drives the impeller 92 to rotate, at this time, under the action of the transmission shaft 93 and the connecting shaft 94, the rotating shaft 82 rotates to drive the feeding spoon 83 to rotate, and then the throwing of materials is realized, so that the oxygen content of the water body is improved, and meanwhile, the utilization rate of the thrown materials is improved.

The embodiments of the present invention are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in this way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims

1. A wind-solar complementary new energy water oxygen supply system is characterized in that: comprising the following steps:

a floating island (1) floating on a water body;

the support rod (2) is fixedly connected to the upper surface of the floating island (1);

the photovoltaic power generation system (3) is connected with the supporting rod (2) and is used for generating electric energy;

the wind power generation system (4) is connected with the supporting rod (2) and is used for generating electric energy;

the storage battery (5) is connected with the floating island (1) and is used for storing electric energy generated by the photovoltaic power generation system (3) and the wind power generation system (4);

the aerator (6) is connected with the storage battery (5) and is used for aerating the water body;

the exhaust pipe (61) is connected with the aerator (6), and the remaining end of the exhaust pipe (61) is spliced into the water body.

2. The wind-solar complementary new energy water body oxygen supply system according to claim 1, wherein: one end of the exhaust pipe (61) deviating from the aerator (6) is connected with an air disc (7).

3. The wind-solar complementary new energy water body oxygen supply system according to claim 2, wherein: the air disk (7) is connected with a turbulence tube (71), and the turbulence tube (71) is fixedly connected to one side of the air disk (7) which is not provided with an air outlet hole; and the turbulence tube (71) gradually forms a tip shape from one side close to the air disk (7) to one side away from the air disk (7).

4. The wind-solar complementary new energy water body oxygen supply system according to claim 1, wherein: the floating island (1) top is connected with throws material spare (8), throws material spare (8) and includes:

the storage box (81) is fixedly connected to the upper surface of the floating island (1) and is used for storing materials;

a rotating shaft (82) penetrates through the storage box (81) and is rotationally connected with the storage box (81);

the feeding spoon (83) is fixedly connected to the circumference of the rotating shaft (82) and is used for throwing materials in the storage box (81);

the supporting rod (2) is connected with a stop piece (10) for stopping the feeding spoon (83);

the exhaust pipe (61) is communicated with a power piece (9) for driving the rotating shaft (82) to rotate.

5. The wind-solar complementary new energy water body oxygen supply system according to claim 4, wherein: the power element (9) comprises:

the installation shell (91), the installation shell (91) is fixedly connected and communicated with the exhaust pipe (61);

an impeller (92), wherein part of the impeller (92) is positioned in the mounting shell (91), and the blades of the impeller (92) are positioned in the exhaust pipe (61);

the transmission shaft (93) penetrates through the mounting shell (91) and is rotationally connected with the mounting shell (91), and the transmission shaft (93) is fixedly connected with the impeller (92) in a coaxial way;

a connecting shaft (94) connecting the rotating shaft (82) and the transmission shaft (93);

a first bevel gear set (95) for connecting the rotating shaft (82) and the connecting shaft (94);

and the second bevel gear group (96) is used for connecting the transmission shaft (93) and the connecting shaft (94).

6. The wind-solar complementary new energy water body oxygen supply system according to claim 4, wherein: the stop piece (10) comprises a stop rod (101) and a stop spring (102), the stop rod (101) is positioned above the storage box (81), and the stop rod (101) is used for stopping the feeding spoon (83); the stop spring (102) is connected with the stop rod (101) and the support rod (2).

7. The wind-solar complementary new energy water body oxygen supply system according to claim 4, wherein: a stop plate (811) is fixedly connected in the storage box (81), two stop plates (811) are arranged, the two stop plates (811) are parallel to each other, and the stop plates (811) are perpendicular to the rotating shaft (82); a discharging hole (812) is formed in one side of the baffle plate (811) close to the lower part of the storage box (81).

8. The wind-solar complementary new energy water body oxygen supply system according to claim 7, wherein: a sleeve (813) is arranged between the side wall of the two stop plates (811) which are away from each other and the inner wall of the storage box (81), and the sleeve (813) is fixedly connected with the storage box (81); the rotating shaft (82) is sleeved in the sleeve (813), and the diameter of the section of the rotating shaft (82) is smaller than the inner diameter of the sleeve (813).