CN113003729A

CN113003729A - Low resistance wind energy water conservancy oxygen boosting equipment of no energy consumption

Info

Publication number: CN113003729A
Application number: CN202110270249.4A
Authority: CN
Inventors: 柯凡; 柯丹; 黄骏
Original assignee: Nanjing Qingzhong Environmental Technology Co ltd
Current assignee: Nanjing Qingzhong Environmental Technology Co ltd
Priority date: 2021-03-12
Filing date: 2021-03-12
Publication date: 2021-06-22

Abstract

The invention discloses a wind energy and water power oxygen enrichment device with no energy consumption and low resistance, which comprises a driving component and a lifting component, the driving component is fixedly connected with the lifting component through a rotating shaft and a supporting seat, the driving component is positioned above the water surface through a floating body, the lifting assembly is positioned below the water surface, the driving assembly is used for driving the lifting assembly under the action of wind power, the lifting assembly is used for disturbing the upper and lower layers of water bodies, the invention has scientific and reasonable structure, safe and convenient use, utilizes wind power to rotate the driving assembly, thereby realizing the function that the driving component drives the lifting component to rotate, the lifting component rotates to lift the water body of the lower layer of water body to the water surface, and then the upper layer and the lower layer of the water body are disturbed, so that the dissolved oxygen of the surface water body is increased, the oxygen enrichment effect of the water body is improved, a good algae growth environment is favorably obtained, and the content of toxic substances is favorably reduced.

Description

Low resistance wind energy water conservancy oxygen boosting equipment of no energy consumption

Technical Field

The invention relates to the technical field of environmental engineering, in particular to a wind energy and water power oxygen enrichment device without energy consumption and with low resistance.

Background

At present, the technology applied to surface water pollution such as lakes, rivers, reservoirs and the like mainly achieves the aim of mixing water bodies in different depths through the physical action of water body circulation so as to disturb the growing environment of algae and further achieve the aim of controlling the growth of algae, enough dissolved oxygen is kept in water by increasing the dissolved oxygen of the water body, degrading organic pollutants in water and removing ammonia nitrogen, chemical reaction for generating toxic substances can be inhibited, the content of the toxic substances (such as ammonia, nitrite, hydrogen sulfide and the like) is reduced, under the condition that enough dissolved oxygen exists, ammonia and hydrogen sulfide harmful to microorganisms can be generated after organic matters in water are rotted, the ammonia can be converted into nitrate by the decomposition action of oxygen consumption of the microorganisms, then the nitrate is converted into nitrate, the hydrogen sulfide is converted into sulfate, and the nitrate and the sulfate are nontoxic to the microorganisms, on the contrary, when the dissolved oxygen in water is insufficient, ammonia and hydrogen sulfide are difficult to decompose, so that the toxic substances are easy to accumulate to the extent of harming the health of microorganisms, and the dissolved oxygen in the surface water body is increased, and the importance of the dissolved oxygen is increased, the existing oxygen enrichment mode comprises deep water body water delivery oxygenation, an oxygen enrichment machine, aeration and the like, and the existing water body oxygen enrichment equipment has the following problems in use: the operation process of the device is complicated, the resource consumption is excessive, the oxygen enrichment effect is not good, and the like, so that the wind energy and water power oxygen enrichment device without energy consumption and with low resistance is urgently needed to solve the problems.

Disclosure of Invention

The invention aims to provide a wind energy and water power oxygen enrichment device with no energy consumption and low resistance, so as to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the non-energy-consumption low-resistance wind energy and water power oxygen enrichment device comprises a driving assembly and a lifting assembly, wherein the driving assembly is fixedly connected with the lifting assembly through a rotating shaft and a supporting seat, the driving assembly is located above the water surface through a floating body, the lifting assembly is located below the water surface, the driving assembly is used for driving the lifting assembly under the action of wind, and the lifting assembly is used for disturbing upper and lower water bodies;

furthermore, the driving assembly comprises circular plates and two first fan blades, two ends of the rotating shaft are fixedly connected with the centers of the circular plates, a plurality of arc-shaped grooves are formed in the two circular plates and are arranged in a quincunx shape by taking the rotating shaft as a Chinese and western direction, a plurality of first fan blades are arranged, the first fan blades are vertically arranged, the cross sections of the fan blades are arranged corresponding to the cross sections of the arc-shaped grooves, two ends of the first fan blades are arranged in an inserted manner with the arc-shaped grooves, one end of the rotating shaft penetrates through one of the circular plates to extend below a horizontal plane and is fixedly connected with the lifting assembly, the middle of the rotating shaft is rotatably connected with the supporting seat, and a floating body is fixedly sleeved outside the supporting seat;

furthermore, the driving assembly comprises a second fan blade, the second fan blade comprises two blades, the two blades are spirally arranged by taking a rotating shaft as a center, one sides of the two blades are fixedly connected with the rotating shaft, the two second blades are vertically arranged, a conical buoy is arranged in the middle of the rotating shaft, two sides of the conical buoy are fixedly connected with a supporting seat through a first support, floating bodies are fixedly arranged at two ends of the supporting seat, the rotating shaft is rotatably connected with the conical buoy and the supporting seat, and one end of the rotating shaft, far away from the second fan blade, penetrates through the conical buoy and the supporting seat to be fixedly connected with the lifting assembly;

furthermore, the lifting assembly comprises a hydraulic circulating blade and a flow guide cover, one end of the rotating shaft is fixedly connected with the hydraulic circulating blade, the interior of the flow guide cover is hollow, the flow guide cover is sleeved outside the hydraulic circulating blade, the top of the flow guide cover is fixedly connected with a floating body through a second support, the side edge of the floating body is fixedly connected with a fixed pile through a fixed cable, and the fixed pile is arranged at the bottom of the water body;

further, the diameter range of the first fan blade is set to be 300-;

further, the hydraulic circulating blade is in a propeller shape and is horizontally arranged, the diameter range of a blade of the hydraulic circulating blade is set to be 80-600mm, the height range of the blade of the hydraulic circulating blade is 30-200mm, and the hydraulic circulating blade is used for exchanging upper and lower layers of water bodies;

furthermore, a box body is arranged in the flow guide cover, one end of the rotating shaft penetrates through the top of the box body and is fixedly connected with a first conical tooth, the rotating shaft is rotatably connected with the box body, two sides of the first conical tooth are meshed with a second conical tooth, the second conical tooth is fixedly connected with one end of a rotating rod, the first conical tooth and the second conical tooth are both positioned in the box body, the rotating rod is horizontally arranged, the other end of the rotating rod penetrates through the box body and is fixedly connected with a hydraulic circulating leaf, the rotating rod is rotatably connected with the box body, the hydraulic circulating leaf is vertically arranged, and two sides of the box body are fixedly connected with the inner wall of the flow guide cover through;

furthermore, a rotating plate is sleeved on the fixed rod and located below the hydraulic circulating blade.

Compared with the prior art, the invention has the following beneficial effects:

1. utilize wind-force to make drive assembly rotate to realize the rotatory function of drive assembly drive lifting means, lifting means rotates and promotes lower floor water body to the water surface, and then disturbs upper and lower floor of water body, increases the dissolved oxygen of surface water body with this, improves water oxygen boosting effect, is favorable to obtaining good alga growing environment, and is favorable to reducing the content of toxic substance.

2. The first arc-shaped fan blade can be suitable for wind in all directions, the middle section of the first arc-shaped fan blade can be used for gathering wind to serve as a concentrated bearing point of wind power, and the rotation efficiency of the first wind blade driven by wind energy is improved.

3. The wind is used as a power source of the whole wind energy and water power oxygen enrichment equipment, the wind energy is converted into kinetic energy, manual starting and stopping equipment is not needed, the oxygen enrichment process can be directly carried out through the wind energy, compared with the traditional oxygen enrichment machine, aeration and other modes, the oxygen enrichment equipment is simple and convenient to operate, does not consume resource energy, and can be implemented without an external power supply equipment.

4. The first fan blade and the second fan blade are simple and convenient to manufacture and beneficial to saving cost, the first fan blade is of an inserting piece type structure and convenient to install and disassemble, the wind energy utilization rate is high, the rotation speed of the hydraulic circulating blade is improved, and therefore the disturbance efficiency of the deep water body is better.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a first schematic view of a driving assembly and a lifting assembly according to the present invention;

FIG. 2 is a top view of a circular plate and an arc-shaped groove of the present invention;

FIG. 3 is a schematic view of a first blade of the present invention;

FIG. 4 is a second schematic structural view of the driving assembly and the lifting assembly of the present invention;

FIG. 5 is a top view of a second bucket of the present invention;

FIG. 6 is a schematic view of a second blade of the present invention;

FIG. 7 is a schematic diagram of the position structure of the rotating rod and the rotating shaft according to the present invention;

in the figure: 1. a drive assembly; 2. a lifting assembly; 11. a rotating shaft; 12. a supporting seat; 13. a circular plate; 14. a first fan blade; 15. an arc-shaped slot; 16. a float; 17. a second fan blade; 171. a blade; 18. a conical buoy; 19. a first bracket; 21. hydraulic circulating leaves; 22. a pod; 23. a second bracket; 24. a first fixing member; 25. a second fixing member; 31. a box body; 32. a first conical tooth; 33. a second tapered tooth; 34. rotating the rod; 35. fixing the rod; 36. and (6) rotating the plate.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1: referring to fig. 1-3, the present invention provides the following technical solutions: a non-energy-consumption low-resistance wind-power hydraulic oxygen enrichment device comprises a driving component 1 and a lifting component 2, wherein the driving component 1 is fixedly connected with the lifting component 2 through a rotating shaft 11 and a supporting seat 12, the driving component 1 is positioned above the water surface through a floating body 16, the lifting component 2 is positioned below the water surface, the driving component 1 is used for driving the lifting component 2 under the action of wind power, and the lifting component 2 is used for disturbing upper and lower layers of water;

drive assembly turns into the kinetic energy of hoisting assembly with wind energy, the pivot is used for supporting drive assembly and hoisting assembly and rotates, thereby realize on the disturbance, the function of lower floor's water, the supporting seat is used for fixed mounting drive assembly, through fixing the body on the water surface, thereby fixed drive assembly and hoisting assembly are in the position of water, therefore, the steam generator is simple in operation, the structure is simple and convenient, do not need the manual work to implement whole oxygen boosting process, and do not need additionally to add power supply unit, utilize wind energy as only drive power, greatly reduced the consumption of the energy, make the water circulation mix in order to reach the water of different water depths through hoisting assembly, can obtain good water environment, be favorable to the microorganism growth.

The driving assembly 1 comprises circular plates 13 and first fan blades 14, the circular plates 13 are provided with two, two ends of a rotating shaft 11 are fixedly connected with the centers of the circular plates 13, the two circular plates 13 are respectively provided with a plurality of arc-shaped grooves 15, the arc-shaped grooves 15 are arranged in a quincunx shape by taking the rotating shaft as the middle and the middle, the first fan blades 14 are provided with a plurality of first fan blades 14, the first fan blades 14 are vertically arranged, the cross sections of the first fan blades 14 are arranged corresponding to the cross sections of the arc-shaped grooves 15, two ends of the first fan blades 14 are arranged in an inserted manner with the arc-shaped grooves 15, one end of the rotating shaft 11 penetrates through one of the circular plates 13 and extends to the position below a horizontal plane to be fixedly connected with the lifting assembly 2, the middle part of;

the upper circular plate and the lower circular plate are used for fixing the first fan blade, the first fan blades are used for transmitting wind energy, the arc-shaped grooves are used for inserting installation of the first fan blades, the supporting seat is used for supporting the rotating shaft, the wind energy is converted into kinetic energy of the lifting assembly through the rotating shaft and the first fan blades, the lifting assembly rotates in the lower water body to achieve disturbance of the water body to enable the water body on the upper layer to exchange with the water body on the lower layer, the arc-shaped first fan blades can be suitable for wind in all directions, the middle section of the arc-shaped first fan blades can play a role in gathering wind and serve as a centralized bearing point of the wind power, the rotating efficiency of the first fan blades driven by the wind energy is improved, the outer side of the protruding position of the arc-shaped first fan blades can serve as a wind blocking function, the wind.

The lifting assembly 2 comprises a hydraulic circulation blade 21 and a flow guide cover 22, one end of the rotating shaft 11 is fixedly connected with the hydraulic circulation blade 21, the interior of the flow guide cover 22 is arranged in a hollow shape, the flow guide cover 22 is sleeved outside the hydraulic circulation blade 21, the top of the flow guide cover 22 is fixedly connected with the floating body 16 through a second support 23, the side edge of the floating body 16 is fixedly connected with a fixed pile 25 through a fixed cable 24, and the fixed pile 25 is arranged at the bottom of a water body;

the hydrologic cycle leaf also rotates simultaneously when pivot pivoted and is used for exchanging lower floor water, in order to reach the oxygen boosting effect, the kuppe is used for water conservancy diversion lower floor water, be favorable to improving the oxygen boosting effect, the kuppe passes through the second support location, the body provides buoyancy for whole oxygen boosting equipment, fixed hawser is arranged in fixing whole oxygen boosting equipment in the water, the spud pile is used for fixing a position bottom the water, the installation is simple, only need pass through the spud pile, fixed hawser and body are fixed with drive assembly and lifting means, this oxygen boosting equipment both can begin the operation, high transmission efficiency, high wind energy utilization rate, good drive effect.

The diameter range of the first fan blade 14 is set to be 300-800mm, the height range of the first fan blade 14 is set to be 600-2500mm, and the first fan blade 14 is made of one of aluminum alloy, stainless steel material and glass fiber reinforced plastic;

the working temperature of the oxygen enrichment equipment is-40 to 80 degrees, the water area range of the oxygen enrichment equipment is 50 x 50m for the water area environment with the water depth range of 1.5 to 10m, the optimal diameter value of the first fan blade acting on the water area environment is 400mm, the optimal height value of the first fan blade is 800mm, and the first fan blade made of the aluminum alloy material is high in strength and light in weight.

The hydraulic circulating blade 21 is in a propeller shape, the hydraulic circulating blade 21 is horizontally arranged, the diameter range of a blade of the hydraulic circulating blade 21 is set to be 80-600mm, the height range of the blade of the hydraulic circulating blade 21 is 30-200mm, and the hydraulic circulating blade 21 is used for exchanging upper and lower layers of water bodies;

the propeller-shaped hydraulic circulating blade is beneficial to improving the efficiency of exchanging upper and lower water bodies and reducing the resistance of water to the blade, the horizontal arrangement of the hydraulic circulating blade means that the horizontal plane where the hydraulic circulating blade is located is vertical to the rotating shaft, for the water area environment, the optimal value of the diameter of the blade of the corresponding hydraulic circulating blade is 300mm, the diameter of the blade of the hydraulic circulating blade is 2-3 times of the height, the blade is more harmonious when in use, when the oxygen enrichment equipment works, the starting wind speed of the first blade is 1.5m/s, and the safe wind speed is 45 m/s.

A box body 31 is arranged in the guide hood 22, one end of a rotating shaft 11 penetrates through the top of the box body 31 and is fixedly connected with a first conical tooth 32, the rotating shaft 11 is rotatably connected with the box body 31, two sides of the first conical tooth 32 are meshed with a second conical tooth 33, the second conical tooth 33 is fixedly connected with one end of a rotating rod 34, the first conical tooth 32 and the second conical tooth 33 are both positioned in the box body 31, the rotating rod 34 is horizontally arranged, the other end of the rotating rod 34 penetrates through the box body 31 and is fixedly connected with the hydraulic circulating leaf 21, the rotating rod 34 is rotatably connected with the box body 31, the hydraulic circulating leaf 21 is vertically arranged, and two sides of the box body 31 are fixedly connected;

if fig. 7, the box is used for fixed pivot and dwang, the pivot is rotated and is used for making first toper tooth rotate, first toper tooth rotates and is used for transmission second toper tooth, second toper tooth rotates and is used for making the dwang rotate, the dwang rotates and is used for making the water conservancy circulation leaf rotate, dwang horizontal arrangement means that the dwang is perpendicular with the pivot, the vertical setting of water conservancy circulation leaf means that the plane at water conservancy circulation leaf place is parallel to each other with the pivot, the plane at water conservancy circulation leaf place is perpendicular with the dwang, be favorable to further improving the efficiency of upper and lower layer water body exchange, with this oxygen boosting effect that increases the water.

The fixed rod 35 is sleeved with a rotating plate 36, and the rotating plate 36 is positioned below the hydraulic circulating blade 21; the rotating plate is used for expanding the water body exchange range, when the hydraulic circulating blade rotates to exchange upper and lower water bodies, the upper water body is driven by the hydraulic circulating blade to move from the upper layer to the lower layer, and at the moment, the water body of the part gives pressure to the rotating plate, so that the rotating plate is pushed to rotate on the rotating rod, the rotating plate rotates to drive the lower water body relative to the hydraulic circulating blade to the position of the hydraulic circulating blade from bottom to top, the hydraulic circulating blade is indirectly pushed to rotate, and the exchange efficiency of the upper and lower water bodies is improved.

Example 2:

as shown in fig. 4-6: the driving assembly 1 comprises a second fan blade 17, the second fan blade 17 comprises two blades 171, the two blades 171 are spirally arranged by taking a rotating shaft 11 as a center, one side of each of the two blades 171 is fixedly connected with the rotating shaft 11, the two second blades 17 are vertically arranged, a conical buoy 18 is arranged in the middle of the rotating shaft 11, two sides of the conical buoy 18 are fixedly connected with a supporting seat 12 through a first support 19, floating bodies 16 are fixedly arranged at two ends of the supporting seat 12, the rotating shaft 11 is rotatably connected with the conical buoy 18 and the supporting seat 12, and one end of the rotating shaft 11, which is far away from the second fan blade 17, penetrates through the conical buoy 18 and the supporting seat 12 to be fixedly connected;

two blades are both spirally arranged on one side of the rotating shaft, and the second fan blade is used for driving the hydraulic circulating blade in the lifting assembly to rotate.

The rest is the same as in example 1.

The working principle of the invention is as follows: firstly, the fixing pile is installed at the bottom of the water body, the fixing cable is connected, the floating body is fixed, after all parts are installed in sequence, the first fan blade rotates around the rotating shaft under the action of wind energy, the hydraulic circulating blade rotates simultaneously when the first fan blade rotates, and at the moment, the upper layer water body and the lower layer water body are disturbed through the hydraulic circulating blade, so that the oxygen enrichment effect of the water body is achieved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a no energy consumption low resistance wind can water conservancy oxygen boosting equipment which characterized in that: including drive assembly (1) and lifting means (2), drive assembly (1) is through pivot (11), supporting seat (12) and lifting means (2) fixed connection, drive assembly (1) is located above the surface of water through body (16), lifting means (2) are located below the surface of water, drive assembly (1) is used for driving lifting means (2) under the wind-force effect, lifting means (2) are used for disturbing upper and lower floor's water.

2. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 1, which is characterized in that: the driving assembly (1) comprises circular plates (13) and first fan blades (14), two circular plates (13) are arranged, two ends of the rotating shaft (11) are fixedly connected with the center of the circular plates (13), a plurality of arc-shaped grooves (15) are formed in the two circular plates (13), the arc-shaped grooves (15) are arranged in a quincunx shape by taking the rotating shaft as the center, the first fan blades (14) are provided with a plurality of first fan blades (14) which are vertically arranged, the cross sections of the first fan blades (14) are arranged corresponding to the cross sections of the arc-shaped grooves (15), two ends of the first fan blades (14) are arranged in an inserting mode with the arc-shaped grooves (15), one end of the rotating shaft (11) penetrates through one circular plate (13) to extend to a position below a horizontal plane and is fixedly connected with the lifting assembly (2), the middle of the rotating shaft (11) is rotatably connected with the supporting seat, the floating body (16) is fixedly sleeved outside the supporting seat (12).

3. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 1, which is characterized in that: drive assembly (1) includes second fan blade (17), second fan blade (17) include two blade (171), two blade (171) are the heliciform setting as the center with pivot (11), two blade (171) one side all with pivot (11) fixed connection, two second blade (17) are vertical setting, pivot (11) middle part is equipped with toper flotation pontoon (18), toper flotation pontoon (18) both sides are through first support (19) and supporting seat (12) fixed connection, supporting seat (12) both ends are fixed and are equipped with body (16), pivot (11) are the rotation with toper flotation pontoon (18), supporting seat (12) and are connected, the one end that second fan blade (17) were kept away from in pivot (11) is passed toper flotation pontoon (18) and supporting seat (12) and lifting unit (2) fixed connection.

4. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 2, which is characterized in that: the diameter range of the first fan blade (14) is set to be 300-800mm, the height range of the first fan blade (14) is set to be 600-2500mm, and the manufacturing material of the first fan blade (14) is one of aluminum alloy, stainless steel material and glass fiber reinforced plastic.

5. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 2 or 3, which is characterized in that: the lifting assembly (2) comprises a hydraulic circulation blade (21) and a flow guide cover (22), one end of the rotating shaft (11) is fixedly connected with the hydraulic circulation blade (21), the flow guide cover (22) is arranged in a hollow manner, the hydraulic circulation blade (21) is sleeved with the flow guide cover (22), the top of the flow guide cover (22) is fixedly connected with the floating body (16) through a second support (23), and the side edge of the floating body (16) is fixedly arranged at the bottom of a water body through a fixing device.

6. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 4, which is characterized in that: the fixing device comprises a first fixing piece (24) and a second fixing piece (25), the side edge of the floating body (16) is fixedly connected with one end of the first fixing piece (24), the other end of the first fixing piece (24) is fixedly connected with the second fixing piece (25), the second fixing piece (25) is arranged at the bottom of the water body, the first fixing piece (24) is one of a cable rope, a hanging rope, a hemp rope, a nylon rope and a steel wire rope, and the second fixing piece (25) is one of a fixing pile, an anchor and a balancing weight.

7. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 5, which is characterized in that: the hydraulic circulating blade (21) is in a propeller shape, the hydraulic circulating blade (21) is horizontally arranged, the diameter range of blades of the hydraulic circulating blade (21) is set to be 80-600mm, the height range of blades of the hydraulic circulating blade (21) is 30-200mm, and the hydraulic circulating blade (21) is used for exchanging upper and lower layers of water bodies.

8. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 5, which is characterized in that: a box body (31) is arranged in the air guide sleeve (22), one end of the rotating shaft (11) penetrates through the top of the box body (31) and is fixedly connected with a first conical tooth (32), the rotating shaft (11) is rotationally connected with the box body (31), two sides of the first conical tooth (32) are meshed with the second conical tooth (33), the second conical teeth (33) are fixedly connected with one end of the rotating rod (34), the first conical teeth (32) and the second conical teeth (33) are both positioned in the box body (31), the rotating rod (34) is horizontally arranged, the other end of the rotating rod (34) penetrates through the box body (31) and is fixedly connected with the hydraulic circulating blade (21), the rotating rod (34) is rotatably connected with the box body (31), the hydraulic circulating blade (21) is vertically arranged, the bottom of the box body (31) is fixedly connected with the inner wall of the air guide sleeve (22) through a fixing rod (35).

9. The non-energy-consumption low-resistance wind-power water oxygen enrichment device of claim 8, which is characterized in that: the fixed rod (35) is sleeved with a rotating plate (36), and the rotating plate (36) is located below the hydraulic circulating blade (21).