CN112065649A

CN112065649A - Wind power generation device capable of reducing wind energy fluctuation

Info

Publication number: CN112065649A
Application number: CN202011076275.5A
Authority: CN
Inventors: 原金恒
Original assignee: Qingdao Jiubao Energy Equipment Technology Co ltd
Current assignee: Qingdao Jiubao Energy Equipment Technology Co ltd
Priority date: 2020-10-10
Filing date: 2020-10-10
Publication date: 2020-12-11

Abstract

The invention relates to the field related to wind energy, and discloses a wind power generation device capable of reducing wind energy fluctuation, which comprises a main box body, wherein a gear transmission cavity is arranged in the main box body, a friction wheel cavity is arranged at the left side of the gear transmission cavity, a turning nut cavity is arranged at the left side of the friction wheel cavity, a conical friction wheel cavity is communicated and arranged at the lower side of the friction wheel cavity, a transmission gear cavity is arranged at the lower side of the left side of the conical friction wheel cavity, a conical tooth cavity is communicated and arranged at the lower side of the transmission gear cavity, a rotating block cavity is arranged at the right side of the conical tooth cavity, the internal variable transmission ratio is automatically adjusted according to wind speed, so that a generator can keep a stable rotating speed to rotate, the stability of the generator for generating electricity is ensured, meanwhile, the main box body can be automatically adjusted according to the wind direction, a fan can always face to, the steering of the generator can be ensured to be consistent, and the unstable power generation caused by the steering change of the generator is greatly reduced.

Description

Wind power generation device capable of reducing wind energy fluctuation

Technical Field

The invention relates to the field related to wind energy, in particular to a wind power generation device capable of reducing wind energy fluctuation.

Background

The kinetic energy generated by the flowing of wind energy and air and the wind energy generation are realized by converting wind energy into electric energy by utilizing a wind turbine, but because the wind speed in the nature is unstable, the energy generated by the wind turbine is unstable, if the wind energy fluctuation is not regulated, the potential safety hazard to the movement of a power grid is easily generated, and meanwhile, the wind direction is continuously changed, so that the wind energy utilization rate of the wind power generation device is greatly reduced, the generated energy is far lower than the ideal level, and the power generation effect is not ideal.

Disclosure of Invention

The invention aims to provide a wind power generation device capable of reducing wind energy fluctuation, which can overcome the defects in the prior art, thereby improving the practicability of equipment.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a wind power generation device capable of reducing wind energy fluctuation, which comprises a main box body, wherein a gear transmission cavity is arranged in the main box body, a friction wheel cavity is arranged at the left side of the gear transmission cavity, a turning nut cavity is arranged at the left side of the friction wheel cavity, a conical friction wheel cavity is communicated and arranged at the lower side of the friction wheel cavity, a transmission gear cavity is arranged at the left lower side of the conical friction wheel cavity, a conical tooth cavity is communicated and arranged at the lower side of the transmission gear cavity, a rotating block cavity is arranged at the right side of the conical tooth cavity, a fan shaft which extends rightwards to the outside and inwards to the gear transmission cavity is arranged in the right end wall of the gear transmission cavity, a fan is fixedly connected at the right end of the fan shaft, a fan transmission gear is fixedly connected at the left end of the fan shaft in a rotating manner, an upper gear transmission shaft which extends rightwards to penetrate through, the tail end of the right side of the upper gear transmission shaft is fixedly connected with an upper transmission gear meshed with the fan transmission gear, the right end wall of the rotating block cavity is connected with a rotating block transmission shaft which extends rightwards into the gear transmission cavity and extends leftwards into the rotating block cavity in a rotating matching manner, the right end of the rotating block transmission shaft is fixedly connected with a lower transmission gear meshed with the fan transmission gear, the left end of the rotating block transmission shaft is fixedly connected with a rotating block, a plurality of sliding block cavities which are circumferentially distributed by taking the rotating block transmission shaft as a center and have outward openings are arranged in the rotating block, sliding blocks are connected in the sliding block cavities in a sliding matching manner, sliding block springs are fixedly connected between the side end faces of the sliding block transmission shafts close to the rotating block and the side end walls of the sliding block cavities close to the rotating block transmission shafts, and baffles positioned, and a baffle spring is fixedly connected between the lower end face of the baffle and the lower end wall of the rotating block cavity, and a baffle pull rope is fixedly connected with the lower end face of the baffle.

On the basis of the technical scheme, the interior normal running fit of end wall is connected with the base under the main tank body, be equipped with the opening rotation gear chamber left in the base, the base outside be equipped with the annular rack chamber that the base set up as central annular, rotate the gear chamber left with annular rack chamber intercommunication, annular rack chamber lateral wall internal fixation is connected with the annular rack that the base set up as central annular, rotation gear chamber lower extreme wall internal rotation fit is connected with upwards extends to transmission gear shaft in the base, the terminal fixedly connected with of transmission gear shaft upside with the transmission gear wheel of annular rack meshing, bevel gear chamber left side is equipped with diversion transmission chamber, diversion transmission chamber left side is equipped with diversion band pulley chamber, diversion transmission chamber downside is equipped with slip bevel gear chamber, end wall internal rotation fit in the base is connected with upwards extends to slip bevel gear intracavity downwardly extends to rotation gear intracavity The tail end of the lower side of the steering bevel gear shaft is fixedly connected with a rotating gear meshed with the transmission gear wheel, and the tail end of the upper side of the steering bevel gear shaft is fixedly connected with a steering bevel gear.

On the basis of the technical scheme, a rotating transmission shaft which extends leftwards and penetrates through the sliding bevel gear cavity to the rotating belt wheel cavity is connected in a rotating and matching manner on the right end wall of the sliding bevel gear cavity, a sliding shaft sleeve positioned in the sliding bevel gear cavity is connected in a spline matching manner on the rotating transmission shaft, the tail ends of the left side and the right side of the sliding shaft sleeve are respectively connected with sliding shaft sleeve seats which are bilaterally symmetrical by taking the steering bevel gear as the center in a rotating and matching manner, a through cavity is arranged in the sliding shaft sleeve seats in a left-right through manner, the rotating transmission shaft penetrates through the through cavity, a sliding shaft sleeve spring is fixedly connected between the end surface of the sliding shaft sleeve seat, which is far away from the side end surface of the steering bevel gear shaft, and the end wall of the sliding bevel gear cavity, which is far away from the side of the steering, the sliding shaft sleeve is fixedly connected with rotating bevel gears which are bilaterally symmetrical by taking the steering bevel gear as a center and can be meshed with the steering bevel gear, the tail end of the left side of the rotating transmission shaft is fixedly connected with a rotating driven gear, and the left side of the rotating belt wheel cavity is provided with a generator fixedly connected with the main box body.

On the basis of the technical scheme, the right end face of the generator is fixedly connected with a generator shaft which extends rightwards and penetrates through the rotating belt wheel cavity and the turning belt wheel cavity to the turning transmission cavity, the generator shaft is fixedly connected with a rotating driving belt wheel positioned in the rotating belt wheel cavity, a rotating transmission belt is connected between the rotating driving belt wheel and the rotating driven gear in a power fit manner, the generator shaft is fixedly connected with a turning driving belt wheel positioned in the turning belt wheel cavity, the right end wall of the turning belt wheel cavity is connected with an end face tooth transmission shaft which extends rightwards and penetrates through the turning transmission cavity to the right end wall of the turning transmission cavity and extends leftwards to the turning belt wheel cavity in a power fit manner, the left end of the end face tooth transmission shaft is fixedly connected with a turning driven belt wheel, and a turning transmission belt is connected between the turning driven belt wheel and the turning driving, spline fit is connected with on the generator shaft and is located the terminal surface tooth axle sleeve, fixedly connected with slip terminal surface tooth is sheathe in to the terminal surface tooth, running fit is connected with the slip connecting rod on the slip terminal surface tooth, slip connecting rod internal rotation fit is connected with and is located the gear bush of slip terminal surface tooth downside, gear bush right side end is fixed with sliding gear, slip connecting rod left end face with fixedly connected with connecting rod spring between the diversion transmission chamber left end wall, slip connecting rod left end face fixedly connected with connecting rod stay cord.

On the basis of the technical scheme, the inner wall of the right end of the turning transmission cavity is in rotating fit connection with an end face gear shaft which extends rightwards into the bevel gear cavity, the end face gear shaft on the left side of the end face gear shaft is fixedly connected with an end face straight gear which can be meshed with the sliding end face gear and the sliding gear, the inner wall of the left lower end of the tapered friction gear cavity is in rotating fit connection with an end face gear shaft which extends leftwards and downwards and extends rightwards into the transmission gear cavity and upwards, the end of the right upper side of the tapered friction gear shaft is fixedly connected with a tapered friction gear, the end of the left lower side of the tapered friction gear shaft is fixedly connected with a transmission gear, the end of the right side of the end face gear shaft is fixedly connected with a bevel gear which is meshed with the transmission gear, the upper gear transmission shaft is fixedly connected with a turning shaft sleeve which is positioned, the left end face and the right end face of the turning nut and the left end wall and the right end wall of the turning nut cavity are fixedly connected with left and right symmetrical turning shaft sleeves, the other end of the connecting rod pull rope is fixedly connected with the right end face of the turning nut, and the upper gear transmission shaft is connected with a friction wheel shaft sleeve in a spline fit mode, wherein the friction wheel shaft sleeve is located in the friction wheel cavity.

On the basis of the technical scheme, the left and right ends of the friction wheel shaft sleeve are respectively connected with a left and right symmetrical shaft sleeve seat in a rotating fit manner, a transmission shaft through cavity is arranged in the shaft sleeve seat in a left and right through manner, the upper gear transmission shaft penetrates through the transmission shaft through cavity, the friction wheel which is abutted against the conical friction wheel is fixedly connected to the friction wheel shaft sleeve, a friction wheel spring is fixedly connected between the left end surface of the left side shaft sleeve seat and the left end wall of the friction wheel cavity, the other end of the baffle pull rope is fixedly connected with the right end surface of the right side shaft sleeve seat, the upper side of the diversion transmission cavity is provided with a nut sliding cavity, the lower end wall of the nut sliding cavity is connected with a wind direction mark rod which extends upwards and penetrates through the nut sliding cavity to the outside in a rotating fit manner, the tail end of the upper side of the wind direction mark rod is fixedly connected with a wind direction mark, the upper end face and the lower end face of the rotating sliding nut and the upper end wall and the lower end wall of the nut sliding cavity are fixedly connected with nut springs which are symmetrical up and down, the other end of the rotating upper pull rope is fixedly connected with the upper end face of the rotating sliding nut, and the other end of the rotating lower pull rope is fixedly connected with the lower end face of the rotating sliding nut.

The invention has the beneficial effects that: according to the inside variable speed drive ratio of wind speed automatic adjustment, make the generator can keep a stable rotational speed to rotate, thereby the stability of generator electricity generation has been guaranteed, main box physical stamina is according to wind direction automatic adjustment simultaneously, make the fan can be all the time just to the wind direction, the wind energy utilization ratio has been improved greatly, the generating efficiency of generator has been ensured, automatic diversion transmission in the main box, no matter make fan corotation or reversal, can both guarantee turning to of generator unanimously, greatly reduced because of the generator turns to the electricity generation unstability that changes and bring.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of an overall structure of a wind power generation device capable of reducing wind energy fluctuation according to the present invention;

FIG. 2 is an enlarged schematic view of A in FIG. 1;

FIG. 3 is an enlarged schematic view of B of FIG. 1;

FIG. 4 is an enlarged schematic view of C in FIG. 1;

fig. 5 is an enlarged schematic view of D in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1-5, a wind power generation device capable of reducing wind energy fluctuation includes a main box 10, a gear transmission chamber 13 is provided in the main box 10, a friction wheel chamber 69 is provided on the left side of the gear transmission chamber 13, a direction-changing nut chamber 62 is provided on the left side of the friction wheel chamber 69, a conical friction wheel chamber 73 is provided on the lower side of the friction wheel chamber 69, a transmission gear chamber 74 is provided on the left lower side of the conical friction wheel chamber 73, a conical tooth chamber 75 is provided on the lower side of the transmission gear chamber 74, a rotation block chamber 28 is provided on the right side of the conical tooth chamber 75, a fan shaft 17 extending rightward to the outside and extending inward into the gear transmission chamber 13 is provided in the right end wall of the gear transmission chamber 13, a fan 16 is fixedly connected to the right end of the fan shaft 17, a fan transmission gear 18 is fixedly connected to the left end of the fan shaft 17, a left end wall of the direction-changing nut chamber 62 is, Friction wheel chamber 69 extremely go up gear drive shaft 14 in the gear drive chamber 13, go up the terminal fixedly connected with in the right side of gear drive shaft 14 with last gear 15 of fan drive gear 18 meshing, rotatory piece chamber 28 right-hand member wall internal rotation cooperation is connected with and extends to right extend to a left side in the gear drive chamber 13 rotatory piece transmission shaft 20 in the rotatory piece chamber 28, rotatory piece transmission shaft 20 right side terminal fixedly connected with the lower drive gear 21 of fan drive gear 18 meshing, rotatory piece transmission shaft 20 left side terminal fixedly connected with rotatory piece 24, be equipped with a plurality of in the rotatory piece 24 with rotatory piece transmission shaft 20 is central circumference distribution and the outside slider chamber 22 of opening, sliding fit is connected with slider 23 in the slider chamber 22, slider 23 is close to rotatory piece transmission shaft 20 side end with slider chamber 22 is close to fixedly connected with slider spring 19 between the rotatory piece transmission shaft 20 wall The rotating block cavity 28 is connected with a baffle 25 positioned on the lower side of the rotating block 24 in a sliding fit mode, a baffle spring 27 is fixedly connected between the lower end face of the baffle 25 and the lower end wall of the rotating block cavity 28, and a baffle pull rope 26 is fixedly connected to the lower end face of the baffle 25.

In addition, in one embodiment, a base 89 is connected to the lower end surface of the main box 10 in a rotationally matched manner, a rotating gear cavity 29 with a leftward opening is arranged in the base 89, an annular rack cavity 31 which is annularly arranged by taking the base 89 as a center is arranged on the outer side of the base 89, the rotating gear cavity 29 is communicated with the annular rack cavity 31 leftward, an annular rack 32 which is annularly arranged by taking the base 89 as a center is fixedly connected to the side wall of the annular rack cavity 31, a transmission gear shaft 91 which extends upwards into the base 89 is connected to the lower end wall of the rotating gear cavity 29 in a rotationally matched manner, a transmission gear 90 which is meshed with the annular rack 32 is fixedly connected to the upper end of the transmission gear shaft 91, a direction-changing transmission cavity 42 is arranged on the left side of the bevel gear cavity 75, a direction-changing belt wheel cavity 54 is arranged on the left side of the direction-changing transmission cavity 42, a sliding bevel gear cavity, the upper end wall of the base 89 is connected with a steering bevel gear shaft 87 which extends upwards to the inside of the sliding bevel gear cavity 83 and extends downwards to the inside of the rotating gear cavity 29 in a rotating matching manner, the tail end of the lower side of the steering bevel gear shaft 87 is fixedly connected with a rotating gear 30 meshed with the transmission large gear 90, and the tail end of the upper side of the steering bevel gear shaft 87 is fixedly connected with a steering bevel gear 88.

In addition, in one embodiment, a rotating transmission shaft 35 extending through the sliding bevel gear chamber 83 to the rotating pulley chamber 36 to the left is connected to the right end wall of the sliding bevel gear chamber 83 in a rotationally fitted manner, a sliding shaft sleeve 82 located in the sliding bevel gear chamber 83 is connected to the rotating transmission shaft 35 in a spline fitted manner, sliding shaft sleeve seats 84 symmetrical left and right about the steering bevel gear 88 are connected to the left and right ends of the sliding shaft sleeve 82 in a rotationally fitted manner, through chambers 86 are arranged in the sliding shaft sleeve seats 84 in a left and right through manner, the rotating transmission shaft 35 passes through the through chambers 86, a sliding shaft sleeve spring 85 is fixedly connected between the end surface of the sliding shaft sleeve seat 84 far away from the steering bevel gear shaft 87 and the end wall of the sliding bevel gear chamber 83 far away from the steering bevel gear shaft 87, a rotating lower pull rope 59 is fixedly connected to the left end surface of the sliding shaft sleeve seat 84, the right end face of the sliding shaft sleeve seat 84 on the right side is fixedly connected with a rotating upper pull rope 57, the sliding shaft sleeve 82 is fixedly connected with rotating bevel gears 81 which are bilaterally symmetrical with the steering bevel gear 88 as a center and can be meshed with the steering bevel gear 88, the tail end of the left side of the rotating transmission shaft 35 is fixedly connected with a rotating driven gear 34, and the left side of the rotating belt wheel cavity 36 is provided with a generator 38 fixedly connected with the main box body 10.

In addition, in one embodiment, a generator shaft 39 extending through the rotating pulley cavity 36, the direction-changing pulley cavity 54 and the direction-changing transmission cavity 42 to the right end face of the generator 38 is fixedly connected with the right end face of the generator 38, a rotating driving pulley 40 located in the rotating pulley cavity 36 is fixedly connected to the generator shaft 39, a rotating transmission belt 37 is connected between the rotating driving pulley 40 and the rotating driven gear 34 in a power fit manner, a direction-changing driving pulley 56 located in the direction-changing pulley cavity 54 is fixedly connected to the generator shaft 39, a face tooth transmission shaft 49 extending through the direction-changing transmission cavity 42 to the right end wall of the direction-changing transmission cavity 42 to the left end and extending into the direction-changing pulley cavity 54 is connected in a rotating fit manner to the right end wall of the direction-changing pulley cavity 54, a direction-changing driven pulley 53 is fixedly connected to the left end face tooth transmission shaft 49, diversion driven pulleys 53 with power fit is connected with diversion driving belt 55 between the diversion driving pulleys 56, spline fit is connected with on the generator shaft 39 and is located face tooth axle sleeve 45, fixedly connected with slip face tooth 43 on the face tooth axle sleeve 45, the cooperation of rotating on the slip face tooth 43 is connected with sliding connecting rod 44, sliding connecting rod 44 internal rotation fit is connected with and is located the gear bush 50 of slip face tooth 43 downside, gear bush 50 right side end is fixed with sliding gear 48, sliding connecting rod 44 left end face with fixedly connected with connecting rod spring 52 between the diversion transmission chamber 42 left end wall, sliding connecting rod 44 left end face fixedly connected with connecting rod stay cord 51.

In addition, in an embodiment, the right end wall of the direction-changing transmission cavity 42 is rotationally and cooperatively connected with an end-face gear shaft 46 extending rightwards into the bevel gear cavity 75, the left end of the end-face gear shaft 46 is fixedly connected with an end-face straight gear 47 capable of being engaged with the sliding end-face gear 43 and the sliding gear 48, the left end wall of the tapered friction gear cavity 73 is rotationally and cooperatively connected with a tapered friction gear shaft 71 extending leftwards and downwards into the transmission gear cavity 74 and extending rightwards and upwards into the tapered friction gear cavity 73, the right end of the tapered friction gear shaft 71 is fixedly connected with a tapered friction gear 72, the left end of the tapered friction gear shaft 71 is fixedly connected with a transmission gear 77, the right end of the end-face gear shaft 46 is fixedly connected with a bevel gear 76 engaged with the transmission gear 77, and the upper gear transmission shaft 14 is fixedly connected with a direction-changing shaft sleeve 79 located in the direction, the upper thread of the direction-changing shaft sleeve 79 is connected with a direction-changing nut 63 which is connected with the direction-changing nut cavity 62 in a sliding fit mode, the left end face and the right end face of the direction-changing nut 63 and the left end wall and the right end wall of the direction-changing nut cavity 62 are fixedly connected with bilaterally symmetrical direction-changing shaft sleeves 80, the other end of the connecting rod pull rope 51 is fixedly connected with the right end face of the direction-changing nut 63, and the upper gear transmission shaft 14 is connected with a friction wheel shaft sleeve 66 which is located in the friction wheel.

In addition, in one embodiment, the left and right ends of the friction wheel shaft sleeve 66 are connected with a bilateral symmetry shaft sleeve seat 67 in a rotating fit manner, a transmission shaft through cavity 68 is arranged in the shaft sleeve seat 67 in a left-right through manner, the upper gear transmission shaft 14 penetrates through the transmission shaft through cavity 68, a friction wheel 65 abutted against the conical friction wheel 72 is fixedly connected to the friction wheel shaft sleeve 66, a friction wheel spring 70 is fixedly connected between the left end surface of the left side shaft sleeve seat 67 and the left end wall of the friction wheel cavity 69, the other end of the baffle pull rope 26 is fixedly connected with the right end surface of the right side shaft sleeve seat 67, a nut sliding cavity 61 is arranged on the upper side of the diversion transmission cavity 42, a wind vane 12 extending upwards to penetrate through the nut sliding cavity 61 to the outside is connected to the lower end wall of the nut sliding cavity 61 in a rotating fit manner, and a wind vane 11 is fixedly connected to, the wind direction indicator rod 12 is connected with a rotating sliding nut 58 in a threaded fit manner, the rotating sliding nut 58 is connected with a nut sliding cavity 61 in a sliding fit manner, vertically symmetrical nut springs 60 are fixedly connected between the upper end face and the lower end face of the rotating sliding nut 58 and the upper end wall and the lower end wall of the nut sliding cavity 61, the other end of the rotating upper pull rope 57 is fixedly connected with the upper end face of the rotating sliding nut 58, and the other end of the rotating lower pull rope 59 is fixedly connected with the lower end face of the rotating sliding nut 58.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-5, when the apparatus of the present invention is in an initial state, the sliding end face teeth 43 are disengaged from the end face spur gear 47, the connecting rod spring 52 is in a compressed state, the connecting rod pull rope 51 is in a relaxed state, the sliding gear 48 is disengaged from the end face spur gear 47 and the direction-changing nut 63 is in the middle position of the direction-changing shaft sleeve 79, the friction wheel 65 is abutted to the large diameter position of the conical friction wheel 72, the rotating sliding nut 58 is in the middle position of the nut sliding cavity 61, the sliding shaft sleeve 82 is in the middle position of the sliding bevel gear cavity 83, the left and right rotating bevel gears 81 and the direction-changing bevel gear 88 are not engaged with the slider 23 and are in the slider cavity 22, the upper end face of the baffle 25 touches the outer circular face of the; sequence of mechanical actions of the whole device: at the start of operation, the wind force drives the fan 16 to rotate in the forward direction, thereby driving the fan shaft 17 to rotate, thereby causing the fan drive gear 18 to rotate, thereby driving the upper drive gear 15 to rotate, thereby causing the upper gear drive shaft 14 to rotate, thereby driving the friction wheel shaft sleeve 66 to rotate, thereby causing the friction wheel 65 to rotate, thereby causing the tapered friction wheel 72 to rotate, thereby driving the tapered friction wheel shaft 71 to rotate, thereby causing the drive gear 77 to rotate, thereby causing the bevel gear 76 to rotate, thereby causing the end face gear shaft 46 to rotate, thereby causing the end face spur gear 47 to rotate, while the upper gear drive shaft 14 rotates to cause the direction-changing shaft sleeve 79 to rotate, thereby causing the direction-changing nut 63 to move rightwards to temporarily disengage from the threaded engagement with the direction-changing shaft sleeve 79, thereby causing the right direction-changing shaft sleeve 80 to compress, the left direction-changing shaft sleeve 80 to stretch, the pull rope connecting rod 51 to be in a relaxed state An engaged state, thereby rotating the sliding end face teeth 43, thereby rotating the end face teeth sleeve 45, thereby rotating the generator shaft 39, thereby generating electricity by the generator 38; meanwhile, the fan transmission gear 18 rotates to drive the lower transmission gear 21 to rotate, so that the rotating block transmission shaft 20 rotates, and the rotating block 24 is driven to rotate, so that the slide block 23 moves towards the side far away from the rotating block transmission shaft 20 under the action of centrifugal force and overcomes the pulling force of the slide block spring 19, so that the baffle plate 25 is pushed to move downwards and overcomes the elastic force of the baffle plate spring 27, so that the baffle plate pull rope 26 is loosened, when the rotating speed of the fan 16 is increased, the right shaft sleeve seat 67 moves leftwards under the action of the pulling force of the friction wheel spring 70, so that the friction wheel shaft sleeve 66 is driven to move leftwards, so that the friction wheel 65 moves leftwards, so that the rotating speed of the friction wheel 65 is increased and is abutted to the large-diameter part of the conical friction wheel 72, and the rotating speed of the conical friction wheel 72 is the same as before due to the, so that the rotational speed of the generator shaft 39 is constant, thereby stabilizing the amount of electricity generated by the generator 38; when the fan 16 rotates reversely, the upper gear transmission shaft 14 rotates reversely to drive the direction-changing shaft sleeve 79 to rotate reversely, so that the direction-changing nut 63 moves leftwards to be temporarily disengaged from the direction-changing shaft sleeve 79, the connecting rod pull rope 51 is pulled to make the sliding connecting rod 44 move leftwards against the elastic force of the connecting rod spring 52, so that the gear shaft sleeve 50 is driven to move leftwards, so that the sliding gear 48 moves leftwards to be engaged with the end face spur gear 47, the sliding end face teeth 43 are disengaged from the sliding gear 48, so that the end face spur gear 47 rotates reversely to drive the sliding gear 48 to rotate forwards, so that the gear shaft sleeve 50 rotates forwards, so that the end face tooth transmission shaft 49 rotates forwards, so that the direction-changing driven pulley 53 rotates forwards, the direction-changing driving pulley 56 is driven to rotate forwards through the direction-changing transmission belt 55, so that the generator shaft 39, the generator 38 can be ensured to generate power stably; when the wind direction changes, if the wind vane 11 is rotated in the forward direction by the change of the wind direction, the wind vane lever 12 is rotated in the forward direction to drive the rotary slide nut 58 to move upward to pull the rotary lower pull rope 59 and rotate the upper pull rope 57 to release, thereby moving the slide bush housing 84 to the left to drive the slide bush 82 to move leftward to engage the right rotary bevel gear 81 with the steering bevel gear 88, at this time, the generator shaft 39 is rotated to drive the rotary drive pulley 40 to rotate, the rotary driven gear 34 is rotated by rotating the drive belt 37 to rotate the rotary drive shaft 35 to rotate, thereby driving the rotary bevel gear 81 to rotate, the right rotary bevel gear 81 is rotated to drive the steering bevel gear 88 to rotate in the forward direction to rotate the steering bevel gear shaft 87 to drive the rotary gear 30 in the forward direction to rotate the drive large gear 90 in the forward direction to drive the annular rack 32 in the forward direction, therefore, the main box body 10 rotates forwards to face the wind direction, when the main box body 10 rotates forwards, the wind vane 11 is always consistent with the wind direction under the action of wind power, the wind vane 11 rotates backwards relative to the main box body 10, the rotating sliding nut 58 moves downwards to the middle position of the nut sliding cavity 61, the rotating upper pull rope 57 is pulled, the rotating lower pull rope 59 is loosened, the right rotating bevel gear 81 is disengaged from the steering bevel gear 88, the left rotating bevel gear 81 is still not engaged with the steering bevel gear 88, the main box body 10 stops rotating, when the wind direction changes, the wind vane 11 rotates backwards, the movement process is opposite to that of the rotating bevel gear 81, the main box body 10 rotates backwards to face the wind direction, and the main box body 10 can always face the wind direction when the wind direction changes.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a can reduce undulant wind power generation set of wind energy, includes the main tank body, its characterized in that: a gear transmission cavity is arranged in the main box body, a friction wheel cavity is arranged on the left side of the gear transmission cavity, a turning nut cavity is arranged on the left side of the friction wheel cavity, a conical friction wheel cavity is communicated and arranged on the lower side of the friction wheel cavity, a transmission gear cavity is arranged on the lower side of the left side of the conical friction wheel cavity, a bevel gear cavity is communicated and arranged on the lower side of the transmission gear cavity, a rotating block cavity is arranged on the right side of the bevel gear cavity, a fan shaft which extends rightwards to the outside and inwards to the gear transmission cavity is arranged in the right end wall of the gear transmission cavity, a fan is fixedly connected to the right end of the fan shaft, a fan transmission gear is fixedly connected to the left end of the fan shaft, an upper gear transmission shaft which extends rightwards to penetrate through the turning nut cavity, the friction wheel cavity and the gear transmission cavity is connected to the left end of the turning nut cavity in a, the right end wall of the rotating block cavity is connected with a rotating block transmission shaft which extends rightwards into the gear transmission cavity and extends leftwards into the rotating block cavity in a matched manner, the right end of the rotating block transmission shaft is fixedly connected with a lower transmission gear which is meshed with the fan transmission gear, the left end of the rotating block transmission shaft is fixedly connected with a rotating block, a plurality of sliding block cavities which are circumferentially distributed by taking the rotating block transmission shaft as a center and are provided with outward openings are arranged in the rotating block, sliding blocks are connected in the sliding block cavities in a matched manner, a sliding block spring is fixedly connected between the side end face of the sliding block close to the rotating block transmission shaft and the side end wall of the sliding block cavity close to the rotating block transmission shaft, a baffle plate positioned at the lower side of the rotating block is connected in the rotating block cavity in a sliding manner, and a baffle, the lower end face of the baffle is fixedly connected with a baffle pull rope.

2. The wind power generation device capable of reducing wind energy fluctuation according to claim 1, wherein: a base is connected in a rotating fit manner in the lower end face of the main box body, a rotating gear cavity with a leftward opening is arranged in the base, an annular rack cavity which is arranged in an annular manner by taking the base as a center is arranged on the outer side of the base, the rotating gear cavity is communicated with the annular rack cavity leftwards, an annular rack which is arranged in an annular manner by taking the base as a center is fixedly connected in the side wall of the annular rack cavity, a transmission large gear shaft which extends upwards into the base is connected in a rotating fit manner in the lower end wall of the rotating gear cavity, a transmission large gear which is meshed with the annular rack is fixedly connected at the tail end of the upper side of the transmission large gear shaft, a turning transmission cavity is arranged on the left side of the bevel gear cavity, a turning belt wheel cavity is arranged on the left side of the turning transmission cavity, a sliding bevel gear cavity is arranged on the lower side of the turning transmission cavity, a turning, the tail end of the lower side of the steering bevel gear shaft is fixedly connected with a rotating gear meshed with the transmission gear wheel, and the tail end of the upper side of the steering bevel gear shaft is fixedly connected with a steering bevel gear.

3. The wind power generation device capable of reducing wind energy fluctuation according to claim 2, wherein: the left end wall and the right end wall of the sliding bevel gear cavity are connected with a rotating transmission shaft which extends leftwards and penetrates through the sliding bevel gear cavity to the rotating belt wheel cavity in a matched mode, the rotating transmission shaft is connected with a sliding shaft sleeve which is located in the sliding bevel gear cavity in a matched mode, the tail ends of the left side and the right side of the sliding shaft sleeve are connected with sliding shaft sleeve seats which are bilaterally symmetrical by taking the steering bevel gear as the center in a matched mode, a through cavity is formed in the sliding shaft sleeve seats in a left-right through mode, the rotating transmission shaft penetrates through the through cavity, the sliding shaft sleeve seats are far away from the side end face of the steering bevel gear shaft and far away from the side end wall of the side of the steering bevel gear shaft, sliding shaft sleeve springs are fixedly connected between the left end face of the sliding shaft sleeve seats and the right end face of the sliding shaft sleeve seats, rotating lower pull ropes are fixedly connected to And the rotating bevel gear is meshed with the bevel gear, the tail end of the left side of the rotating transmission shaft is fixedly connected with a rotating driven gear, and a generator fixedly connected with the main box body is arranged on the left side of the rotating belt wheel cavity.

4. A wind power plant for reducing wind energy fluctuations according to claim 3, further comprising: the right end face of the generator is fixedly connected with a generator shaft which extends rightwards and penetrates through the rotating belt wheel cavity, the turning belt wheel cavity to the turning transmission cavity, the generator shaft is fixedly connected with a rotating driving belt wheel positioned in the rotating belt wheel cavity, a rotating transmission belt is connected between the rotating driving belt wheel and the rotating driven gear in a power fit manner, the generator shaft is fixedly connected with a turning driving belt wheel positioned in the turning belt wheel cavity, the right end wall of the turning belt wheel cavity is connected with an end face tooth transmission shaft which extends rightwards and penetrates through the turning transmission cavity to the right end wall of the turning transmission cavity and extends leftwards to the turning belt wheel cavity in a power fit manner, the left end of the end face tooth transmission shaft is fixedly connected with a turning driven belt wheel, and a turning transmission belt is connected between the driven belt wheel and the turning driving belt wheel, spline fit is connected with on the generator shaft and is located the terminal surface tooth axle sleeve, fixedly connected with slip terminal surface tooth is sheathe in to the terminal surface tooth, running fit is connected with the slip connecting rod on the slip terminal surface tooth, slip connecting rod internal rotation fit is connected with and is located the gear bush of slip terminal surface tooth downside, gear bush right side end is fixed with sliding gear, slip connecting rod left end face with fixedly connected with connecting rod spring between the diversion transmission chamber left end wall, slip connecting rod left end face fixedly connected with connecting rod stay cord.

5. A wind power plant for reducing the fluctuation of wind energy according to claim 4, wherein: the inner wall of the right end of the turning transmission cavity is in internal rotation fit connection with a terminal surface toothed shaft which extends rightwards into the conical toothed cavity, the terminal of the left side of the terminal surface toothed shaft is fixedly connected with a terminal surface straight gear which can be engaged with the sliding end surface tooth and the sliding gear, the terminal of the left lower end of the left end of the conical friction wheel cavity is in internal rotation fit connection with a conical friction wheel shaft which extends leftwards and upwards into the conical friction wheel cavity and extends rightwards and upwards into the conical friction wheel cavity, the terminal of the right upper side of the conical friction wheel shaft is fixedly connected with a conical friction wheel, the terminal of the left lower side of the conical friction wheel shaft is fixedly connected with a transmission gear, the terminal of the right side of the terminal surface toothed shaft is fixedly connected with a bevel gear which is engaged with the transmission gear, the turning transmission shaft is, the left end face and the right end face of the turning nut and the left end wall and the right end wall of the turning nut cavity are fixedly connected with left and right symmetrical turning shaft sleeves, the other end of the connecting rod pull rope is fixedly connected with the right end face of the turning nut, and the upper gear transmission shaft is connected with a friction wheel shaft sleeve in a spline fit mode, wherein the friction wheel shaft sleeve is located in the friction wheel cavity.

6. The wind power generation device capable of reducing wind energy fluctuation according to claim 5, wherein: the tail ends of the left side and the right side of the friction wheel shaft sleeve are respectively connected with a left symmetrical shaft sleeve seat and a right symmetrical shaft sleeve seat in a rotating fit manner, a transmission shaft through cavity is arranged in the shaft sleeve seat in a left-right through manner, the upper gear transmission shaft penetrates through the transmission shaft through cavity, the friction wheel which is abutted against the conical friction wheel is fixedly connected onto the friction wheel shaft sleeve, a friction wheel spring is fixedly connected between the left end surface of the shaft sleeve seat on the left side and the left end wall of the friction wheel cavity, the other end of the baffle stay cord is fixedly connected with the right end surface of the shaft sleeve seat on the right side, a nut sliding cavity is arranged on the upper side of the turning transmission cavity, a wind direction mark rod which extends upwards and penetrates through the nut sliding cavity to the outside is connected into the lower end wall of the nut sliding cavity in a rotating fit manner, a wind direction mark rod is fixedly connected, the upper end face and the lower end face of the rotating sliding nut and the upper end wall and the lower end wall of the nut sliding cavity are fixedly connected with nut springs which are symmetrical up and down, the other end of the rotating upper pull rope is fixedly connected with the upper end face of the rotating sliding nut, and the other end of the rotating lower pull rope is fixedly connected with the lower end face of the rotating sliding nut.