阅读说明：本技术 一种海上利用风能与潮汐能发电的系统 (System for generating power by utilizing wind energy and tidal energy on sea ) 是由 王泽彬 于 2021-08-19 设计创作，主要内容包括：本发明涉及海上风力与潮汐能发电领域,具体是一种海上利用风能与潮汐能发电的系统,包括浮动装置,所述浮动装置的上方固定设有发电装置固定浮板,所述浮动装置的下方设有装置固定件,所述装置固定块与所述浮动装置之间设有液压连接管,所述浮动装置两侧设有两涡轮,所述发电装置固定浮板的上方固设有转向件,所述转向件上设有六块海浪压力感应板,所述装置转向件上方固设有风力发电腔。可以将风力和潮汐能利用并发电。(The invention relates to the field of offshore wind power and tidal power generation, in particular to a system for generating power by utilizing wind energy and tidal energy at sea, which comprises a floating device, wherein a power generation device fixing floating plate is fixedly arranged above the floating device, a device fixing piece is arranged below the floating device, a hydraulic connecting pipe is arranged between the device fixing block and the floating device, two turbines are arranged at two sides of the floating device, a steering piece is fixedly arranged above the power generation device fixing floating plate, six sea wave pressure sensing plates are arranged on the steering piece, and a wind power generation cavity is fixedly arranged above the device steering piece. Wind power and tidal energy can be harnessed and electricity generated.)

1. A system for generating electricity from wind and tidal energy at sea, comprising a floating installation (6), characterized in that: the device is characterized in that a power generation device fixing floating plate (1) is fixedly arranged above the floating device (6), a device fixing piece (4) is arranged below the floating device (6), a hydraulic connecting pipe (5) is arranged between the device fixing block (4) and the floating device (6), two power generation turbines (2) are arranged on two sides of the floating device (6), a steering piece (9) is fixedly arranged above the power generation device fixing floating plate (1), six sea wave pressure induction plates (7) are arranged on the steering piece (9), and a wind power generation cavity (10) is fixedly arranged above the device steering piece (9).

2. A system for harnessing wind and tidal power at sea, according to claim 1, wherein: the utility model discloses a floating device, including floating device (6), floating device (6) and second motor connecting pipe (44), floating device (6) inside is equipped with first generator (43), one side of first generator (43) is connected with first motor connecting pipe (3), two electricity generation turbines (2) have set firmly on first motor connecting pipe (3), first generator (43) opposite side is equipped with second motor connecting pipe (44), equally be equipped with two electricity generation turbines (2) on second motor connecting pipe (44), floating device (6) below is equipped with power generation facility mounting (4), set firmly three hydraulic pressure connecting pipe (5) on wind power generation chamber (10) in floating device (6) link to each other.

3. A system for harnessing wind and tidal power at sea, according to claim 1, wherein: the steering part (9) is provided with six telescopic hydraulic connecting columns (8) distributed in a regular hexagon outside, six sea wave pressure sensing plates (7) are fixedly arranged on the six hydraulic connecting columns (8), the six telescopic hydraulic connecting columns (8) extend to six movable blocks (14) inside the steering part (9), the six movable blocks (14) are distributed in a regular hexagon, one side, far away from the direction of the connecting columns (8), of the six movable blocks (14) is in an arc shape, the six arc shapes wind the center inside the floating device (6) and are distributed in a circular shape, one sides of the arc surfaces of the six movable blocks (14) are provided with transmission rods (15) with transmission gears, the bottom inside the steering part (9) is provided with six conical gear fixing parts (49) distributed in a hexagonal shape, and the six fixing parts are respectively provided with conical gears (16), be equipped with on six conical gear (16) the vertical direction rather than engaged with shelves pole (18), one side that wind power generation chamber (10) is close to steering gear (9) is equipped with rotates spliced pole (20), it extends to rotate spliced pole (20) one side fixedly connected with turning block (19) of steering gear (9) inside.

4. A system for harnessing wind and tidal power at sea, according to claim 1, wherein: the wind power generation cavity (10) is in a regular hexagon shape, two fan blade mounting holes (13) are arranged on one surface and the back surface opposite to the one surface, two air flow induction pressure plates (11) are fixedly arranged on the side, provided with the fan blades, of the wind power generation cavity (10) in the parallel direction, two power generation fan blades (12) are arranged at the positions of the two fan blade mounting holes (13) which are concentric, the four generating fan blades (12) are fixedly arranged on four fan blade generating pieces (41) positioned in the generating mechanism, one side of the rotating connecting column (20) at the bottom of the power generation mechanism is fixedly provided with a generator sealed cavity (21), a second generator (22) is fixedly arranged in the generator sealed cavity (21), the four fan blade power generation parts (41) are connected with the second generator (22) through fixed connecting rods (42), three wedge blocks (23) which are uniformly distributed in a circular shape are fixedly arranged above the generator sealed cavity (21).

5. A system for harnessing wind and tidal power at sea, according to claim 1, wherein: a positive pressure mechanism transmission connecting piece (51) is fixedly arranged above the generator sealed cavity (21), the other side of the positive pressure mechanism transmission connecting piece (51) is fixedly provided with an air positive pressure cavity (25), three arc-shaped blocks (24) are fixedly arranged on one side of the air positive pressure cavity (25) close to the generator sealed cavity (21), an annular air channel (50) is arranged outside the positive pressure mechanism transmission connecting piece (51), five groups of twenty air through holes (26) in each group are radially arranged on the wall of the air positive pressure cavity (25), a rotatable through hole cover (52) is arranged outside the air positive pressure cavity (25) of each air through hole (26), a through hole cover stop block (53) is fixedly arranged in each through hole cover (52) close to the air positive pressure cavity (25), a heating rod (28) is arranged in the air positive pressure cavity (25), and a spiral sheet (27) is fixedly arranged on the heating rod.

6. A system for harnessing wind and tidal power at sea, according to claim 1, wherein: an air partition plate (46) is arranged above one side, far away from the generator sealed cavity (21), of the air positive pressure cavity (25), a first air pumping pump (30) and a second air pumping pump (35) are fixedly arranged on two sides of the air partition plate (46), a second air through hole (29) is formed in the position, where the air pumping pump (30) is arranged, of the air partition plate (46), an air treatment cavity (32) is arranged above the wind power generation cavity (10), the air treatment cavity (32) is connected with the first air pumping pump (30) and the second air pumping pump (35) through an air treatment pipeline (31), four air treatment filter plates are arranged in the air treatment cavity (32), air drying plates (33) are arranged on two sides of the air treatment cavity (32), a salt particle treatment plate (34) is arranged in the middle of the air treatment cavity, a third air conveying pipe (36) is fixedly arranged at the other end of the second air pumping pump (35), air treatment chamber (32) internal fixation is equipped with scraper blade (38) have been set firmly to one side of third air delivery pipe (36), third air delivery pipe (36) with set firmly on second generator (22) pipeline rotation connecting piece (37) link to each other and insert in generator closed chamber (21), third air delivery pipe (36) are in be equipped with a third air through hole (52) in generator closed chamber (21), wind power generation chamber (10) bottom is equipped with salt grain deflector (39) of undercut, salt grain deflector (39) are gone up to open there is salt grain discharge hole (40).

Technical Field

The invention relates to the field of offshore wind power and tidal power generation, in particular to a system for generating power by utilizing wind energy and tidal power at sea.

Background

In the field of current offshore power generation devices, most equipment generates power by singly utilizing wind energy or tidal energy, so that although single natural energy can be efficiently used for power generation, other natural resources for power generation can be ignored, the utilization of the energy is obviously lost, meanwhile, the equipment is fixedly arranged in a single direction on the sea, for the sea wind and tidal energy with uncertain directions, a power generation mechanism can not be ensured to face the sea wind and the tide, in addition, most equipment can be corroded by sea salt mist, finally, the power generation equipment generates a large amount of heat during working, and if the heat cannot be well treated, the working efficiency of a motor can be greatly influenced. Therefore, the design of the device which can automatically turn according to the directions of sea wind and tide, can jointly utilize the sea wind and the tide energy to generate electricity, prevent the equipment from being corroded by salt mist and solve the problem of heat generation of the generator is very significant.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a system for generating power by using wind energy and tidal energy on the sea, which can automatically turn according to the directions of sea wind and tide, can utilize the sea wind and the tidal energy together to generate power, prevents equipment from being corroded by salt fog, and solves the problem of heat generation of a generator.

In order to achieve the purpose, the invention adopts the following technical scheme: a system for generating power by utilizing wind energy and tidal energy at sea comprises a floating device, and is characterized in that: the device is characterized in that a power generation device fixing floating plate is fixedly arranged above the floating device, a device fixing piece is arranged below the floating device, a hydraulic connecting pipe is arranged between the device fixing block and the floating device, two power generation turbines are arranged on two sides of the floating device, a steering piece is fixedly arranged above the power generation device fixing floating plate, six sea wave pressure sensing plates are arranged on the steering piece, and a wind power generation cavity is fixedly arranged above the device steering piece.

Preferably, the inside first generator that is equipped with of floating installation, one side of first generator is connected with first motor connecting pipe, two electricity generation turbines have set firmly on the first motor connecting pipe, first generator opposite side is equipped with the second motor connecting pipe, be equipped with two electricity generation turbines on the second motor connecting pipe equally, the floating installation below is equipped with the power generation facility mounting, the last three hydraulic pressure connecting pipes that have set firmly of power generation mechanism in floating installation links to each other.

Preferably, the steering part outside is equipped with six scalable hydraulic pressure spliced poles that are regular hexagon and distribute, six fixed six wave pressure induction plates that are equipped with on the hydraulic pressure spliced pole, six scalable hydraulic pressure spliced poles extend to six movable blocks inside the steering part, six movable blocks are regular hexagon and distribute, just one side that six movable blocks kept away from the direction of spliced pole is the arc form and six arc forms are circular distribution around the floating installation center, six movable block arc face one sides are equipped with the transfer line of taking drive gear, the inside bottom of steering part is equipped with six conical gear mountings that are hexagonal and distribute, be equipped with conical gear on six mountings respectively, be equipped with rather than the engaged with shelves pole in six conical gear vertical directions, one side that the electricity generation mechanism is close to the steering part is equipped with the rotation spliced pole, the rotating connecting column extends to one side of the inside of the steering piece, and a rotating block is fixedly connected to the rotating connecting column.

Preferably, the wind power generation cavity is in a regular hexagon shape, two fan blade mounting holes are formed in one surface and the opposite back surface of the wind power generation cavity, the surface provided with the fan blades is fixedly provided with two air flow dynamic pressure plates on two sides of the wind power generation cavity in the parallel direction, two power generation fan blades are arranged at the positions of the two fan blade mounting holes which are concentric, the four power generation fan blades are fixedly arranged on four fan blade power generation parts positioned in the power generation mechanism, a generator sealed cavity is fixedly arranged on one side of the rotating connecting column positioned at the bottom of the power generation mechanism, a second generator is fixedly arranged in the generator sealed cavity, the four fan blade power generation parts are connected with the second generator through fixed connecting rods, three wedge blocks which are uniformly distributed in a circular shape are fixedly arranged above the generator sealed cavity, and a positive pressure mechanism transmission connecting piece is fixedly arranged above the generator sealed cavity, malleation mechanism transmission connecting piece opposite side has set firmly the air and has just pressed the chamber, the air is just pressed the chamber and is close to one side in generator airtight chamber has set firmly three arc piece, malleation mechanism transmission connecting piece is equipped with annular air passageway outward, radially opening on the air is just pressed the chamber wall has five groups, twenty air vent of every group, every air vent is located the air is just pressed the chamber and is equipped with rotatable through-hole lid outward, every the through-hole lid be close to the air is just pressed the intracavity and has set firmly the through-hole lid dog, the air is just pressed the intracavity and is equipped with the heating rod, a flight has set firmly on the heating rod.

Preferably, an air partition plate is arranged above one side of the air positive pressure cavity far away from the generator closed cavity, a first air pumping pump and a second air pumping pump are fixedly arranged on two sides of the air partition plate, a second air through hole is formed in the pumping pressure opening of the air pumping pump by the air partition plate, an air treatment cavity is arranged above the generating mechanism and is connected with the first air pumping pump and the second air pumping pump through an air treatment pipeline, four air treatment filter plates are arranged in the air treatment cavity, air drying plates are arranged on two sides of the air treatment cavity, a salt particle treatment plate is arranged in the middle of the air treatment cavity, a third air conveying pipe is fixedly arranged at the other end of the second air pumping pump, the third air conveying pipe is connected with a pipeline rotating connecting piece fixedly arranged on a second generator and is connected into the generator closed cavity, and a scraper plate is fixedly arranged on one side of the third air conveying pipe fixedly arranged in the air treatment cavity, the third air conveying pipe is arranged in the generator sealed cavity and is provided with a third air through hole, the bottom of the wind power generation cavity is provided with a salt particle guide plate which is sunken downwards, and a salt particle discharge hole is formed in the salt particle guide plate.

Has the advantages that: the invention provides a system for generating power by utilizing wind energy and tidal energy at sea by improving. Compared with the prior art, the method has the following improvements and advantages:

the wind power generation and tidal power generation device of the device are combined, so that the offshore natural resources are fully utilized.

2, through the automatic steering piece of the device, the power generation fan blades and the power generation turbine in the device can always face against sea wind and tide, and the power generation working efficiency can be greatly improved.

3, the possibility of equipment damage can be greatly reduced by the salt mist corrosion prevention treatment mechanism of the device, the service life of the equipment is prolonged, and the maintenance cost is reduced.

4, the generator is subjected to heat treatment in the device, and the air in the treated pit is introduced into the closed generator cavity, so that the power of the generator is greatly improved.

Drawings

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

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

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

FIG. 4 is a cross-sectional view taken along line B-B of FIG. 1;

FIG. 5 is a cross-sectional view taken at C-C of FIG. 1;

FIG. 6 is a cross-sectional view taken at D-D in FIG. 1;

in the figure: the device comprises a floating device 6, a power generation device fixing floating plate 1, a device fixing piece 4 and a hydraulic connecting pipe 5, wherein two power generation turbines 2, a steering piece 9, a sea wave pressure sensing plate 7, a wind power generation cavity 10, a first power generator 43, a first motor connecting pipe 3, the power generation turbines 2, a second motor connecting pipe 44, the hydraulic connecting pipe 5, a hydraulic connecting column 8, a movable block 14, a transmission rod 15, a conical gear fixing piece 49, a conical gear 16, a stop lever 18, a rotating connecting column 20, a rotating block 19, a fan blade mounting hole 13, an air flow sensing pressing plate 11, a power generation fan blade 12, a fan blade power generation piece 41, a generator sealed cavity 21, a second power generator 22, a fixed connecting rod 42, a wedge 23, a positive pressure mechanism transmission connecting piece 51, an air positive pressure cavity 25, an arc-shaped block 24, an annular air channel 50, an air through hole 26, a heating rod 28 and a spiral sheet 27 are arranged on two sides of the floating device 6, the device comprises an air partition plate 46, a first air pumping pump 30, a second air pumping pump 35, a second air through hole 29, an air treatment cavity 32, an air treatment pipeline 31, the air treatment cavity 32, an air drying plate 33, a salt particle treatment plate 34, a third air conveying pipe 36, a scraping plate 38, a pipeline rotating connecting piece 37, a third air through hole 52, a salt particle guide plate 39, a salt particle discharge hole 40, a through hole cover 52 and a through hole cover stop block 53.

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.

With reference to the attached drawings 1-6, the system for generating power by utilizing wind energy and tidal energy on the sea comprises a floating device 6, a power generation device fixing floating plate 1 is fixedly arranged above the floating device 6, a device fixing piece 4 is arranged below the floating device 6, a hydraulic connecting pipe 5 is arranged between the device fixing block 4 and the floating device 6, two power generation turbines 2 are arranged on two sides of the floating device 6, a steering piece 9 is fixedly arranged above the power generation device fixing floating plate 1, six sea wave pressure sensing plates 7 are arranged on the steering piece 9, and a wind power generation cavity 10 is fixedly arranged above the device steering piece 9.

Referring to fig. 1, a first generator 43 is arranged inside a floating device 6, a first motor connecting pipe 3 is connected to one side of the first generator 43, two power generation turbines 2 are fixedly arranged on the first motor connecting pipe 3, a second motor connecting pipe 44 is arranged on the other side of the first generator 43, two power generation turbines 2 are also arranged on the second motor connecting pipe 44, a power generation device fixing part 4 is arranged below the floating device 6, and three hydraulic connecting pipes 5 are fixedly arranged on a wind power generation cavity 10 and connected with the floating device 6.

With reference to fig. 5, six telescopic hydraulic connection columns 8 which are distributed in a regular hexagon shape are arranged on the outer side of a steering member 9, six sea wave pressure sensing plates 7 are fixedly arranged on the six hydraulic connection columns 8, the six telescopic hydraulic connection columns 8 extend to six movable blocks 14 inside the steering member 9, the six movable blocks 14 are distributed in a regular hexagon shape, one sides of the six movable blocks 14 far away from the connection columns 8 are in an arc shape and are distributed in a circular shape around the center inside a floating device 6, one sides of arc surfaces of the six movable blocks 14 are provided with transmission rods 15 with transmission gears, six conical gear fixing pieces 49 which are distributed in a hexagon shape are arranged at the bottom inside the steering member 9, conical gears 16 are respectively arranged on the six fixing pieces, stop rods 18 which are meshed with the six conical gears 16 are arranged in the vertical direction, and a rotating connection column 20 is arranged on one side of a wind power generation cavity 10 close to the steering member 9, a rotating block 19 is fixedly connected to one side of the rotating connecting column 20 extending to the interior of the steering member 9.

Referring to the attached drawing 3, the wind power generation cavity 10 is in a regular hexagon shape, two fan blade mounting holes 13 are arranged on one surface and the back surface opposite to the one surface, two air flow sensing pressing plates 11 are fixedly arranged on the two sides of the wind power generation cavity 10 in the direction parallel to the one surface on which the fan blades are arranged, two power generation fan blades 12 and four power generation fan blades 12 are arranged at the concentric positions of the two fan blade mounting holes 13, the four fan blade fixing members 41 are fixedly arranged on four fan blade fixing members 41 positioned in the power generation mechanism, a generator sealed cavity 21 is fixedly arranged on one side of a rotating connecting column 20 positioned at the bottom of the power generation mechanism, a second generator 22 is fixedly arranged in the generator sealed cavity 21, the four fan blade fixing members 41 are connected with the second generator 22 through fixing connecting rods 42, three round uniformly distributed wedges 23 are fixedly arranged above the generator sealed cavity 21, a positive pressure mechanism transmission connecting member 51 is fixedly arranged above the generator sealed cavity 21, the other side of the positive pressure mechanism transmission connecting piece 51 is fixedly provided with an air positive pressure cavity 25, one side of the air positive pressure cavity 25, which is close to the generator sealed cavity 21, is fixedly provided with three arc-shaped blocks 24, an annular air channel 50 is arranged outside the positive pressure mechanism transmission connecting piece 51, five groups are radially arranged on the wall of the air positive pressure cavity 25, twenty air through holes 26 in each group, each air through hole 26 is positioned outside the air positive pressure cavity 25 and is provided with a rotatable through hole cover 52, each through hole cover 52 is fixedly provided with a through hole cover stop block 53 in the air positive pressure cavity 25, a heating rod 28 is arranged in the air positive pressure cavity 25, and a spiral sheet 27 is fixedly arranged on the heating rod.

Referring to fig. 4, an air partition plate 46 is disposed above one side of the air positive pressure chamber 25 far from the generator sealed chamber 21, a first air pumping pump 30 and a second air pumping pump 35 are fixedly disposed on two sides of the air partition plate 46, a second air through hole 29 is disposed at a pumping port of the air pumping pump 30 on the air partition plate 46, an air processing chamber 32 is disposed above the wind power generation chamber 10, the air processing chamber 32 is connected to the first air pumping pump 30 and the second air pumping pump 35 through an air processing pipeline 31, four air processing filter plates are disposed in the air processing chamber 32, air drying plates 33 are disposed on two sides of the air processing chamber 32, a salt particle processing plate 34 is disposed in the middle of the air processing chamber, a third air delivery pipe 36 is fixedly disposed at the other end of the second air pumping pump 35, a scraper 38 is fixedly disposed on one side of the third air delivery pipe 36 fixedly disposed in the air processing chamber 32, the third air delivery pipe 36 is connected to the generator sealed chamber 21 through a pipeline rotary connector 37 fixedly disposed on the second generator 22, the third air conveying pipe 36 is provided with a third air through hole 52 in the generator closed cavity 21, the bottom of the wind power generation cavity 10 is provided with a salt particle guide plate 39 which is sunken downwards, and the salt particle guide plate 39 is provided with a salt particle discharge hole 40.

The working principle of the invention is as follows:

firstly, the device is arranged on a floating device fixing plate, a power generation device fixing floating plate 1 is fixedly arranged above a floating device 6, a device fixing part 4 is arranged below the floating device 6, a hydraulic connecting pipe 5 is arranged between the device fixing block 4 and the floating device 6, the device can be slowly adjusted by the hydraulic connecting pipe when the sea wave is large, the influence on the internal structure of the device caused by overlarge height difference is reduced, two power generation turbines 2 are arranged at two sides of the floating device 6, a first power generation motor 43 is arranged in the floating device 6, one side of the first power generation motor 43 is connected with a first motor connecting pipe 3, two power generation turbines 2 are fixedly arranged on the first motor connecting pipe 3, a second motor connecting pipe 44 is arranged at the other side of the first power generation motor 43, two power generation turbines 2 are also arranged on the second motor connecting pipe 44, and power generation and storage are carried out through the second power generation motor when the two turbines 2 rotate,

when the direction of the sea changes, the sea waves exert impact force on one of the sea wave pressure sensing plates 7, the sea wave pressure sensing plates 7 can squeeze the hydraulic connecting column 8 under the impact force, the movable block 14 connected on the hydraulic connecting column 8 can slide inwards, one side of the arc-shaped surface of the movable block 14 is provided with a transmission rod 15 with a transmission gear, the transmission rod 15 is meshed with the bevel gear 16, the stop lever 18 engaged with the bevel gear 16 is pushed upwards by the bevel gear 16, one side of the rotating connecting column 20 extending into the steering part 9 is fixedly connected with a rotating block 19, one side provided with fan blades is fixedly provided with two air flow sensing pressure plates 11 at two sides of the wind power generation cavity 10 in the parallel direction, sea wind blows the air flow sensing pressure plates 11 to enable the power generation device to rotate at the rotating block 19, at the moment, the rotating block 19 can be blocked by the stop lever 18 to stop moving, and at the moment, the wind power generation device is just stopped in the direction facing the sea wind to generate power.

When the power generation mechanism faces sea wind, the four power generation fan blades 12 are fixedly arranged on four fan blade power generation parts 41 positioned in the power generation mechanism, a generator sealed cavity 21 is fixedly arranged on one side of the rotating connecting column 20 positioned at the bottom of the power generation mechanism, a second generator 22 is fixedly arranged in the generator sealed cavity 21, the four fan blade power generation parts 41 are connected with the second generator 22 through fixed connecting rods 42, and the four fan blade power generation parts 41 transmit power generated by the fan blades to the second generator 22.

When sea wind is sucked into the wind power generation cavity 10 through the power generation fan blades 12, the sea wind is pumped into the air processing cavity by the first air pumping and pressing pump 30, the sea wind is dried and chemically treated in the air treatment cavity 32 to be changed into air with low moisture content and low salt content, the second air pumping pump 35 pumps the treated air to the third air delivery pipe 36, at the moment, the air in the third air delivery pipe 36 is blown by the sea wind in the wind power generation cavity 10, the temperature of the air is delivered to the generator sealed cavity 21, the power generation efficiency of the second generator 22 is improved, at this time, the high-heat air generated by the operation of the second generator 22 in the generator sealed cavity 21 is sucked into the air positive pressure cavity 25 by the rotating spiral sheet 27, and after the water vapor is removed by heating, the high-heat air enters the wind power generation cavity 10 again through the air through hole 26, and a primary air circulation is completed.

When the secondary power generation device works for a period of time, salt particles are possibly attached to the outer wall of the air positive pressure cavity 25 and the outer wall of the third air conveying pipe 36, three wedge blocks 23 which are uniformly distributed in a circular shape are fixedly arranged above the generator sealed cavity 21, a positive pressure mechanism transmission connecting piece 51 is fixedly arranged above the generator sealed cavity 21, the air positive pressure cavity 25 is fixedly arranged on the other side of the positive pressure mechanism transmission connecting piece 51, three arc blocks 24 are fixedly arranged on one side, close to the generator sealed cavity 21, of the air positive pressure cavity 25, when the arc blocks 24 move upwards on the wedge blocks 23 along with the rotation of the air positive pressure cavity 25, the arc blocks vibrate after completely passing through the wedge blocks 23, the salt particles on the outer wall of the air positive pressure cavity 25 are vibrated to the bottom of the wind power generation cavity 10, at the moment, the third air conveying pipe 36 rotates along with a pipeline rotating connecting piece 37 connected to the second generator 22, at the moment, a scraper 38 is fixedly arranged on one side, provided with the third air conveying pipe 36, in the air processing cavity 32, the salt particles adhered to the outer wall of the third air delivery pipe 36 will fall down by friction and also fall to the bottom of the wind power generation chamber 10, the bottom of the wind power generation chamber 10 is provided with a downward-concave salt particle guide plate 39, and the salt particle guide plate 39 is provided with a salt particle discharge hole 40 for discharging the precipitated salt particles.

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.