CN215595791U

CN215595791U - Adjustable wind power generation device

Info

Publication number: CN215595791U
Application number: CN202120684319.6U
Authority: CN
Inventors: 王宝石; 黄新章; 陈向羽; 关铁成; 杨斌; 宋颖
Original assignee: Shenyang Institute of Engineering
Current assignee: Liaoning Xinneng Shuzhi Technology Co.,Ltd.
Priority date: 2021-04-02
Filing date: 2021-04-02
Publication date: 2022-01-21
Anticipated expiration: 2031-04-02

Abstract

The utility model provides an adjustable wind power generation device, which belongs to the field of wind power generation and comprises a bottom plate, a lifting assembly, a rotating assembly, a turning assembly and a telescopic assembly, wherein the bottom plate is horizontally arranged, the lifting assembly is vertically arranged on the bottom plate, an opening assembly is arranged in the lifting assembly, the opening assembly is spliced with the lifting assembly, the top end of the opening assembly extends out of the lifting assembly, the rotating assembly is rotatably arranged at the top of the opening assembly, the turning assembly is arranged at the top of the rotating assembly, the telescopic assembly is arranged on the rotating assembly, a driving assembly is arranged on the telescopic assembly, and the driving assembly is in transmission fit with the telescopic assembly. The wind power generator is convenient to adjust according to the wind power, so that the power generation is convenient when the wind power is small, and the wind power is better utilized to generate power.

Description

Adjustable wind power generation device

Technical Field

The utility model relates to the field of wind power generation, in particular to an adjustable wind power generation device.

Background

Traditional wind power generation set is when carrying out wind power generation, the paddle is generally bigger, need dismantle the paddle when transporting the paddle, then install after transporting the assigned position, it is more troublesome, and the paddle is heavy, need use large-scale crane to dismantle when dismantling, the resource has been wasted, the paddle in addition can not make the paddle rotate when the amount of wind is less, inconvenient length to the paddle is adjusted, can not better utilize wind-force, the device in addition is when using, can not go the direction that changes the flabellum according to the wind direction when carrying out wind power generation, cause the waste of partial wind power resource.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an adjustable wind power generation device, which solves the problems that the length of a paddle is inconvenient to adjust, wind power cannot be better utilized, and when the device is used, the direction of a fan blade cannot be changed according to the wind direction while wind power generation is carried out, so that partial wind power resources are wasted.

The utility model provides an adjustable wind power generation device which comprises a bottom plate, a lifting assembly, a rotating assembly, a turning assembly and a telescopic assembly, wherein the bottom plate is horizontally arranged, the lifting assembly is vertically arranged on the bottom plate, an opening assembly is arranged in the lifting assembly, the opening assembly is spliced with the lifting assembly, the top end of the opening assembly extends out of the lifting assembly, the rotating assembly is rotatably arranged at the top of the opening assembly, the turning assembly is arranged at the top of the rotating assembly, the telescopic assembly is arranged on the rotating assembly, a driving assembly is arranged on the telescopic assembly, and the driving assembly is in transmission fit with the telescopic assembly.

In the above technical scheme, furtherly, lifting unit includes dead lever, lifting ring, backing roll and axis of rotation, the vertical setting of dead lever is on the bottom plate, lifting ring overlaps to be established in the middle section of dead lever, and sets up the three recess that sets up along angles such as lifting ring circumference on the lateral wall of lifting ring, the backing roll is equipped with threely, and three backing roll sets up in three recess along angles such as lifting ring circumference, the axis of rotation is equipped with threely, and three axis of rotation sets up respectively in three recess, and the both ends of every rotating ring all with lifting ring fixed connection, three the backing roll is established respectively in three axis of rotation.

In the above technical solution, further, the opening assembly includes a lifting motor, a lifting screw, a fixed plate, a moving ring, connecting rollers, a rotating disc and a telescopic spring, the fixed plate is disposed in the fixed rod, the fixed plate is located above the inner bottom wall of the fixed rod, the lifting motor is disposed at the bottom of the fixed plate, the lifting screw is disposed at the top of the fixed plate, the output end of the lifting motor is fixedly connected with the bottom end of the lifting screw, the rotating disc is sleeved at the top of the lifting screw, three sliding grooves are disposed at the bottom of the rotating disc, the moving ring is sleeved on the lifting screw, three connecting rollers are disposed, the three connecting rollers are disposed on the outer side wall of the moving ring at equal angles along the circumferential direction of the moving ring, one end of each connecting roller is hinged to the moving ring, the other end of each connecting roller extends into the rotating disc, and each connecting roller is slidably connected with one sliding groove, the telescopic springs are three and are respectively arranged in the three sliding grooves, and two ends of each telescopic spring are respectively fixedly connected with one connecting roller and the rotating disc.

In the above technical scheme, furtherly, rotating assembly includes rotary disk, L template, rotating electrical machines, rotating gear, first driven gear and connecting axle, the rotary disk rotates to set up on the rotary disk, and is equipped with in the rotary disk and places the chamber, the intracavity is being placed in the L template setting, rotating electrical machines installs on the lateral wall of L template, rotating gear all rotates with first driven gear and installs the top at the rotary disk, and rotating electrical machines's output runs through L template and rotary disk and rotating gear fixed connection, rotating gear meshes with first driven gear mutually, the vertical top that sets up at rotating gear of connecting axle.

In the above technical solution, further, the turnover assembly includes a turnover box, a turnover motor, a turnover gear, a second driven gear, a turnover shaft, and two hinged rollers, the turnover box is disposed at the top end of the connecting shaft, and the top of the turnover box is provided with a 20866;, a sliding groove of the type, the turnover motor is disposed on the side wall of the turnover box, the turnover gear is disposed in the turnover box, and the output end of the turnover motor penetrates through the side wall of the turnover box and is fixedly connected with the turnover gear, the turnover shaft is slidably disposed in the sliding groove, and the second driven gear is sleeved on one end of the turnover shaft, the turnover gear is engaged with the second driven gear, the two hinged rollers are vertically disposed in the turnover box, the top end of one hinged roller is hinged with one end of the other hinged roller, the other end of the other hinged roller is fixedly connected with the turnover shaft, the telescopic assembly is arranged at the other end of the turnover shaft.

In the above technical solution, further, the retractable assembly includes a rotating frame, four blades and four retractable members, the rotating frame is disposed on the turning shaft, the four blades are disposed on the outer side wall of the rotating frame at equal angles along the circumferential direction of the rotating frame, and each blade is provided with a slot therein, one end of each of the four retractable members is disposed in the rotating frame, and the other end of each of the four retractable members extends into the four blades, the four retractable members are engaged with each other, each retractable member includes a retractable gear, a retractable screw, a riser and a retractable rod, the retractable screw is disposed in one blade, the riser is disposed on the retractable screw, the outer side wall of the riser is fixedly connected with the inner side wall of one blade, the retractable gear is disposed on the retractable screw, and the retractable gear is disposed in the rotating frame, the retractable rod is disposed on the retractable screw, and the outer side wall of the telescopic rod is connected with the inner side wall of one fan blade in a sliding manner.

In the above technical scheme, furtherly, drive assembly includes driving motor, drive screw, drive gear and live-rollers, the one end setting of live-rollers is on a telescopic screw, and in the other end of live-rollers extended to four extensible member, drive gear sets up on the other end of live-rollers, driving motor sets up on the lateral wall of swivel mount, drive screw sets up in the swivel mount, and drive screw meshes with drive gear mutually, driving motor's output runs through the lateral wall and the drive screw fixed connection of swivel mount.

In the above technical scheme, further, the outer side wall of the fixing rod is provided with spiral threads.

In the above technical scheme, further, the top of upset box is equipped with solar panel.

In the above technical solution, further, the upper section of the lifting screw is not provided with a spiral thread.

Compared with the prior art, the beneficial effect of this application lies in:

firstly, the lifting ring is moved along the length direction of the fixed rod by rotating the lifting ring, the height of the wind power generation device is adjusted, the supporting roller is turned over and is abutted against the lifting ring, so that the wind power generation device is supported, the lifting motor rotates to drive the lifting screw fixedly connected with the output end of the lifting screw to rotate, the lifting screw rotates to drive the moving ring sleeved on the lifting screw to rotate, the moving ring rotates to synchronously drive the rotating disc to ascend, when the moving ring ascends to the upper section of the lifting screw, the telescopic spring can bounce the connecting roller from one end of the sliding groove to the other end under the action of self elasticity, so that the three connecting rollers are opened and can rotate to be vertical axis wind power generation, and the gyro force of a wind wheel in wind direction is reduced.

Secondly, when the horizontal axis wind power is used for generating power, the rotating gear fixedly connected with the output end of the rotating motor can be driven to rotate by the rotation of the rotating motor, the rotating gear drives the first driven gear meshed with the rotating gear to rotate, the first driven gear drives the connecting shaft fixedly connected with the first driven gear to rotate, the connecting shaft drives the overturning box fixedly connected with the connecting shaft to rotate, the overturning box can drive the telescopic component to rotate by the rotation of the overturning box, the facing direction of the utility model is changed according to the difference of the wind direction, or the overturning motor drives the overturning gear fixedly connected with the output end of the overturning gear to rotate, the overturning gear drives the second driven gear meshed with the overturning gear to rotate, the second driven gear drives the overturning shaft to rotate by taking the hinged roller as the center in the sliding groove, the facing direction can be better matched with the wind direction to change, the waste of resources is avoided, when the wind power is too large, the driving motor rotates, the driving screw fixedly connected with the output end of the driving screw is driven to rotate, the driving screw drives the driving gear meshed with the driving screw to rotate, so that the rotating roller is driven to rotate, the rotating roller drives one telescopic screw to rotate, the telescopic screw rotates to drive the telescopic gear sleeved on the telescopic screw to rotate, the four telescopic screws synchronously rotate, and the telescopic rod sleeved on the telescopic screw moves out of the fan blade under the action of the spiral grains in opposite directions, so that the length of the fan blade is increased, strong wind power is resisted, and the damage of the fan blade caused by the over-fast rotation of the fan blade is prevented.

Drawings

In order to more clearly illustrate the embodiments of the present 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 some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic perspective view of an adjustable wind power generation device according to an embodiment of the present invention;

FIG. 2 is a front view of an adjustable wind power plant provided in an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a spreading assembly of the adjustable wind power generation device provided by the embodiment of the utility model;

FIG. 4 is a schematic structural diagram of a rotating assembly of the adjustable wind power generation device according to an embodiment of the present invention;

FIG. 5 is a cross-sectional view taken along line A-A of FIG. 4 according to an embodiment of the present invention;

FIG. 6 is a schematic structural diagram of a turning assembly of the adjustable wind power generation device provided by the embodiment of the utility model;

FIG. 7 is a cross-sectional view taken along line B-B of FIG. 6 according to an embodiment of the present invention

FIG. 8 is a schematic structural diagram of a telescopic assembly of the adjustable wind power generation device according to the embodiment of the present invention;

FIG. 9 is a cross-sectional view taken along line C-C of FIG. 7 according to an embodiment of the present invention;

FIG. 10 is an enlarged view at D of FIG. 8 according to an embodiment of the present invention;

FIG. 11 is a schematic structural diagram of an extension spring of an adjustable wind turbine according to an embodiment of the present invention;

fig. 12 is a schematic structural diagram of a rotating shaft of an adjustable wind power generation device according to an embodiment of the present invention.

Reference numerals:

100-bottom plate, 200-lifting component, 201-fixed rod, 202-lifting ring, 203-supporting roller, 204-rotating shaft, 300-opening component, 301-lifting motor, 302-lifting screw rod, 303-fixed plate, 304-moving ring, 305-connecting roller, 306-rotating disc, 307-telescopic spring, 400-rotating component, 401-rotating disc, 402-L template, 403-rotating motor, 404-rotating gear, 405-first driven gear, 406-connecting shaft, 500-overturning component, 501-overturning box, 502-overturning motor, 503-overturning gear, 504-second driven gear, 505-overturning shaft, 506-hinged roller, 600-telescopic component, 601-rotating frame, and the like, 602-fan blades, 603-telescopic parts, 6031-telescopic gears, 6032-telescopic screws, 6033-vertical plates, 6034-telescopic rods, 700-driving components, 701-driving motors, 702-driving screws, 703-driving gears, 704-rotating rollers and 800-solar panels.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention.

The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model.

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.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 12, the application provides an adjustable wind power generation device, including bottom plate 100, lifting unit 200, rotating assembly 400, upset subassembly 500 and flexible subassembly 600, bottom plate 100 level sets up, lifting unit 200 is vertical setting on bottom plate 100, and is equipped with in lifting unit 200 and opens subassembly 300, open subassembly 300 and lifting unit 200 and peg graft mutually, and open the top of subassembly 300 and extend to outside lifting unit 200, rotating assembly 400 rotates the top that sets up opening subassembly 300, upset subassembly 500 sets up the top at rotating assembly 400, flexible subassembly 600 sets up on rotating unit 400, and is equipped with drive assembly 700 on flexible subassembly 600, drive assembly 700 and flexible subassembly 600 transmission fit.

Further, compared with the prior art, the utility model has the beneficial effects that: the utility model provides an adjustable wind power generation device which comprises a base plate 100, a lifting assembly 200, a rotating assembly 400, a turning assembly 500 and a telescopic assembly 600, wherein the base plate 100 is horizontally arranged, the lifting assembly 200 is vertically arranged on the base plate 100, an opening assembly 300 is arranged in the lifting assembly 200, the opening assembly 300 is spliced with the lifting assembly 200, the top end of the opening assembly 300 extends out of the lifting assembly 200, the rotating assembly 400 is rotatably arranged at the top of the opening assembly 300, the turning assembly 500 is arranged at the top of the rotating assembly 400, the telescopic assembly 600 is arranged on the rotating assembly 400, a driving assembly 700 is arranged on the telescopic assembly 600, and the driving assembly 700 is in transmission fit with the telescopic assembly 600. The utility model provides an adjustable wind power generation device, which solves the problems that the length of a paddle is inconvenient to adjust, wind power cannot be better utilized, and when the device is used, the direction of a fan blade 602 cannot be changed according to the wind direction while wind power generation is carried out, so that partial wind power resources are wasted.

Further, the lifting ring 202 is moved along the length direction of the fixed rod 201 by rotating the lifting ring 202, the height of the utility model is adjusted, the supporting roller 203 is turned over, the supporting roller 203 is abutted against the lifting ring 202, so that the utility model is supported, the lifting motor 301 is rotated to drive the lifting screw 302 fixedly connected with the output end of the lifting screw to rotate, the lifting screw 302 rotates to drive the moving ring 304 sleeved on the lifting screw to rotate, the moving ring 304 rotates to synchronously drive the rotating disc 306 to ascend, when the moving ring 304 ascends to the upper section of the lifting screw 302, the telescopic spring 307 can bounce the connecting roller 305 from one end to the other end of the sliding groove under the action of self elasticity, so that the three connecting rollers 305 are opened and can be rotated to vertical axis wind power generation, and the gyroscopic force of the wind wheel when facing the wind is reduced.

Furthermore, when using horizontal axis wind power to generate electricity, the rotation motor 403 can rotate to drive the rotation gear 404 fixedly connected with the output end thereof to rotate, the rotation gear 404 rotates to drive the first driven gear 405 engaged with the rotation gear to rotate, the first driven gear 405 rotates to drive the connection shaft 406 fixedly connected with the rotation gear 406 to rotate, the connection shaft 406 rotates to drive the turnover box 501 fixedly connected with the rotation gear to rotate, the turnover box 501 rotates to drive the telescopic component 600 to rotate, the facing direction of the utility model is changed according to the difference of wind directions, or the turnover motor 502 rotates to drive the turnover gear 503 fixedly connected with the output end thereof to rotate, the turnover gear 503 rotates to drive the second driven gear 504 engaged with the turnover shaft to rotate, the second driven gear 504 rotates to drive the turnover shaft 505 to rotate in the sliding groove by taking the hinge roller 506 as the center, so as to better match the wind direction to change the facing direction, when the wind power is too large, the driving motor 701 rotates to drive the driving screw 702 fixedly connected with the output end of the driving screw to rotate, the driving screw 702 rotates to drive the driving gear 703 engaged with the driving screw to rotate, so as to drive the rotating roller 704 to rotate, the rotating roller 704 drives one telescopic screw 6032 to rotate, the telescopic screw 6032 rotates to drive the telescopic gear 6031 sleeved on the telescopic screw 6032 to rotate, so that the four telescopic screws 6032 rotate synchronously, the telescopic rod 6034 sleeved on the telescopic screw 6032 is moved out of the fan blade 602 under the action of the spiral grains in the opposite directions, so that the length of the fan blade 602 is increased, stronger wind power is resisted, and the fan blade 602 is prevented from being damaged due to too fast rotation.

Specifically, the lifting assembly 200 comprises a fixing rod 201, a lifting ring 202, three supporting rollers 203 and a rotating shaft 204, the fixing rod 201 is vertically arranged on the bottom plate 100, the lifting ring 202 is sleeved on the middle section of the fixing rod 201, three grooves which are arranged along the circumferential direction of the lifting ring 202 at equal angles are formed in the outer side wall of the lifting ring 202, three supporting rollers 203 are arranged in the three grooves along the circumferential direction of the lifting ring 202 at equal angles, three rotating shafts 204 are arranged in the three grooves respectively, two ends of each rotating ring are fixedly connected with the lifting ring 202, the three supporting rollers 203 are sleeved on the three rotating shafts 204 respectively, the lifting ring 202 moves along the length direction of the fixing rod 201 by rotating the lifting ring 202, the height of the lifting assembly is adjusted, the supporting rollers 203 are turned over, and the supporting rollers 203 are abutted against the lifting ring 202, thereby supporting the present invention for supporting the present invention.

Specifically, the opening assembly 300 includes a lifting motor 301, a lifting screw 302, a fixing plate 303, a moving ring 304, a connecting roller 305, a rotating disc 306 and a telescopic spring 307, the fixing plate 303 is disposed in the fixing rod 201, the fixing plate 303 is located above the bottom wall of the fixing rod 201, the lifting motor 301 is disposed at the bottom of the fixing plate 303, the lifting screw 302 is disposed at the top of the fixing plate 303, the output end of the lifting motor 301 is fixedly connected with the bottom end of the lifting screw 302, the rotating disc 306 is sleeved at the top of the lifting screw 302, three sliding grooves are disposed at the bottom of the rotating disc 306, the moving ring 304 is sleeved on the lifting screw 302, the connecting rollers 305 are three, the three connecting rollers 305 are disposed on the outer side wall of the moving ring 304 at equal angles along the circumferential direction of the moving ring 304, one end of each of the three connecting rollers 305 is hinged to the moving ring 304, and the other end of each connecting roller 305 extends into the rotating disc 306, each connecting roller 305 is connected with a sliding groove in a sliding mode, the number of the telescopic springs 307 is three, the three telescopic springs 307 are respectively arranged in the three sliding grooves, two ends of each telescopic spring 307 are respectively fixedly connected with one connecting roller 305 and the rotating disc 306, the lifting motor 301 rotates to drive the lifting screw 302 fixedly connected with the output end of the lifting screw to rotate, the lifting screw 302 rotates to drive the moving ring 304 sleeved on the lifting screw to rotate, the moving ring 304 rotates to synchronously drive the rotating disc 306 to ascend, when the moving ring 304 ascends to the upper section of the lifting screw 302, the telescopic springs 307 can enable the connecting rollers 305 to be popped from one end to the other end of the sliding grooves under the action of self elastic force, the three connecting rollers 305 are enabled to be opened, vertical axis wind power generation can be achieved, and the gyroscopic force when a wind wheel faces the wind is reduced.

Specifically, the rotating assembly 400 comprises a rotating disc 401, an L-shaped plate 402, a rotating motor 403, a rotating gear 404, a first driven gear 405 and a connecting shaft 406, the rotating disc 401 is rotatably disposed on the rotating disc 306, a placing cavity is disposed in the rotating disc 401, the L-shaped plate 402 is disposed in the placing cavity, the rotating motor 403 is mounted on a side wall of the L-shaped plate 402, the rotating gear 404 and the first driven gear 405 are both rotatably mounted on the top of the rotating disc 401, an output end of the rotating motor 403 penetrates through the L-shaped plate 402 and the rotating disc 401 and is fixedly connected with the rotating gear 404, the rotating gear 404 is meshed with the first driven gear 405, the connecting shaft 406 is vertically disposed on the top of the rotating gear 404, the rotating motor 403 rotates to drive the rotating gear 404 fixedly connected with the output end thereof to rotate, and the rotating gear 404 rotates to drive the first driven gear 405 meshed therewith to rotate, the first driven gear 405 rotates to drive the connecting shaft 406 fixedly connected with the first driven gear to rotate, the connecting shaft 406 rotates to drive the turnover box 501 fixedly connected with the connecting shaft to rotate, the turnover box 501 rotates to drive the telescopic assembly 600 to rotate, and the facing direction of the utility model is changed according to different wind directions.

Specifically, the turnover assembly 500 includes a turnover box 501, a turnover motor 502, a turnover gear 503, a second driven gear 504, a turnover shaft 505 and hinge rollers 506, the turnover box 501 is disposed at the top end of the connecting shaft 406, a sliding groove in a shape of a' 20866, the other end of the other hinge roller 506 is fixedly connected with the turning shaft 505, the telescopic assembly 600 is arranged at the other end of the turning shaft 505, the turning motor 502 rotates to drive the turning gear 503 fixedly connected with the output end of the turning motor to rotate, the turning gear 503 rotates to drive the second driven gear 504 meshed with the turning gear to rotate, the second driven gear 504 rotates to drive the turning shaft 505 to rotate in the sliding groove by taking the hinge roller 506 as the center, the facing direction can be changed by better matching with the wind direction, and resource waste is avoided.

Specifically, the telescopic assembly 600 includes a rotating frame 601, fan blades 602 and four telescopic parts 603, the rotating frame 601 is disposed on the turning shaft 505, the fan blades 602 are four, the four fan blades 602 are disposed on the outer side wall of the rotating frame 601 along the circumferential direction of the rotating frame 601 at equal angles, and each fan blade 602 is provided with a slot therein, one end of each telescopic part 603 is disposed in the rotating frame 601, the other end of each telescopic part 603 extends into the four fan blades 602, the four telescopic parts 603 are engaged with each other, each telescopic part 603 includes a telescopic gear 6031, a telescopic screw 6032, a vertical plate 6033 and a telescopic rod 6034, the telescopic screw 6032 is disposed in one fan blade 602, the vertical plate 6033 is sleeved on the telescopic screw 6032, the outer side wall of the vertical plate 6033 is fixedly connected with the inner side wall of one fan blade 602, the telescopic gear 6031 is disposed on the telescopic screw 6032, and the telescopic gear 6031 is located in the rotating frame 601, the telescopic rod 6034 is sleeved on the telescopic screw 6032, and the outer side wall of the telescopic rod 6034 is in sliding connection with the inner side wall of one fan blade 602, when the wind power is too large, under the driving of the driving component 700, one telescopic screw 6032 is driven to rotate, the telescopic screw 6032 rotates to drive the telescopic gear 6031 sleeved on the telescopic screw 6032 to rotate, so that the four telescopic screws 6032 synchronously rotate, the telescopic rod 6034 sleeved on the telescopic screw 6032 moves out of the fan blade 602 under the action of the spiral threads in opposite directions, thereby increasing the length of the fan blade 602, resisting stronger wind power, and preventing the fan blade 602 from being damaged due to too fast rotation.

Specifically, the driving assembly 700 includes a driving motor 701, a driving screw 702, a driving gear 703 and a rotating roller 704, one end of the rotating roller 704 is disposed on one telescopic screw 6032, the other end of the rotating roller 704 extends into four telescopic members 603, the driving gear 703 is disposed at the other end of the rotating roller 704, the driving motor 701 is disposed on a side wall of the rotating frame 601, the driving screw 702 is disposed in the rotating frame 601, the driving screw 702 is engaged with the driving gear 703, an output end of the driving motor 701 penetrates through the side wall of the rotating frame 601 to be fixedly connected with the driving screw 702, when the wind power is too large, the driving motor 701 rotates to drive the driving screw 702 fixedly connected with the output end to rotate, the driving screw 702 rotates to drive the driving gear 703 engaged therewith to rotate, thereby driving the rotating roller 704 to rotate, the rotating roller 704 drives the telescopic assembly 600 to rotate, the size of the fan blades 602 is changed, so that the fan blades are convenient to use and transport.

Specifically, the outer side wall of the fixing rod 201 is provided with a spiral thread, so that the height of the fixing rod can be changed.

Particularly, the top of the turnover box 501 is provided with the solar panel 800, so that wind power and solar power can be generated at the same time conveniently, and the power generation speed is increased.

Specifically, the upper section of the lifting screw 302 is not provided with a spiral thread, so that the moving plate can idle.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the utility model has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims

1. The utility model provides an adjustable wind power generation set which characterized in that: including bottom plate, lifting unit, rotating assembly, upset subassembly and flexible subassembly, the bottom plate level sets up, lifting unit is vertical setting on the bottom plate, and is equipped with in the lifting unit and opens the subassembly, open the subassembly and peg graft mutually with lifting unit, and open the top of subassembly and extend to outside the lifting unit, rotating assembly rotates and sets up the top of opening the subassembly, the upset subassembly sets up the top at rotating assembly, flexible subassembly sets up on rotating assembly, and is equipped with drive assembly on the flexible subassembly, drive assembly and flexible subassembly transmission cooperation.

2. The adjustable wind power plant of claim 1, wherein: lifting unit includes dead lever, lifting ring, backing roll and axis of rotation, the vertical setting of dead lever is on the bottom plate, lifting ring overlaps to be established in the middle section of dead lever, and sets up the three recess that sets up along angles such as lifting ring circumference on the lateral wall of lifting ring, the backing roll is equipped with threely, and three backing roll sets up in three recess along angles such as lifting ring circumference, the axis of rotation is equipped with threely, and three axis of rotation sets up respectively in three recess, and the both ends of every swivel becket all with lifting ring fixed connection, threely the backing roll is established respectively in three axis of rotation.

3. The adjustable wind power plant of claim 2, wherein: the opening assembly comprises a lifting motor, a lifting screw rod, a fixed plate, a moving ring, connecting rollers, a rotating disc and three telescopic springs, wherein the fixed plate is arranged in the fixed rod, the fixed plate is positioned above the inner bottom wall of the fixed rod, the lifting motor is arranged at the bottom of the fixed plate, the lifting screw rod is arranged at the top of the fixed plate, the output end of the lifting motor is fixedly connected with the bottom end of the lifting screw rod, the rotating disc is sleeved at the top of the lifting screw rod, three sliding grooves are formed in the bottom of the rotating disc, the moving ring is sleeved on the lifting screw rod, the three connecting rollers are arranged on the outer side wall of the moving ring at equal angles along the circumferential direction of the moving ring, one ends of the three connecting rollers are hinged with the moving ring, the other ends of the three connecting rollers extend into the rotating disc, each connecting roller is connected with one sliding groove in a sliding manner, and the three telescopic springs are arranged, three expanding springs are respectively arranged in the three sliding grooves, and two ends of each expanding spring are respectively fixedly connected with one connecting roller and one rotating disc.

4. The adjustable wind power plant of claim 3, wherein: the rotary assembly comprises a rotary disc, an L-shaped plate, a rotary motor, a rotary gear, a first driven gear and a connecting shaft, the rotary disc is rotatably arranged on the rotary disc, a placing cavity is formed in the rotary disc, the L-shaped plate is arranged in the placing cavity, the rotary motor is arranged on the side wall of the L-shaped plate, the rotary gear and the first driven gear are both rotatably arranged at the top of the rotary disc, the output end of the rotary motor penetrates through the L-shaped plate, the rotary disc and the rotary gear fixedly connected, the rotary gear is meshed with the first driven gear, and the connecting shaft is vertically arranged at the top of the rotary gear.

5. The adjustable wind power plant of claim 4, wherein: the turnover assembly comprises a turnover box, a turnover motor, a turnover gear, a second driven gear, a turnover shaft and a hinge roller, the turnover box is arranged at the top end of the connecting shaft, the top of the turnover box is provided with a sliding groove in a shape of a '20866', the turnover motor is arranged on the side wall of the turnover box, the turnover gear is arranged in the turnover box, the output end of the turnover motor penetrates through the side wall of the turnover box and is fixedly connected with the turnover gear, the turnover shaft is arranged in the sliding groove in a sliding manner, the second driven gear is sleeved on one end of the turnover shaft, the turnover gear is meshed with the second driven gear, two hinge rollers are arranged, one hinge roller is vertically arranged in the turnover box, and the top of one articulated roller is articulated mutually with the one end of another articulated roller, the other end and the trip shaft fixed connection of another articulated roller, telescopic component sets up on the other end of trip shaft.

6. The adjustable wind power plant of claim 5, wherein: the telescopic component comprises a rotating frame, fan blades and four telescopic pieces, the rotating frame is arranged on the turnover shaft, the four fan blades are arranged on the outer side wall of the rotating frame at equal angles along the circumferential direction of the rotating frame, and each fan blade is internally provided with a slot, one end of each of the four telescopic pieces is arranged in the rotating frame, the other ends of the four telescopic parts extend into the four fan blades respectively, the four telescopic parts are mutually meshed, each telescopic part comprises a telescopic gear, a telescopic screw rod, a vertical plate and a telescopic rod, the telescopic screw rod is arranged in one fan blade, the vertical plate is sleeved on the telescopic screw rod, the outer side wall of the vertical plate is fixedly connected with the inner side wall of one fan blade, the telescopic gear is arranged on the telescopic screw rod, and the telescopic gear is positioned in the rotating frame, the telescopic rod is sleeved on the telescopic screw rod, and the outer side wall of the telescopic rod is in sliding connection with the inner side wall of one fan blade.

7. The adjustable wind power plant of claim 6, wherein: the drive assembly includes driving motor, driving screw, drive gear and live-rollers, the one end setting of live-rollers is on a telescopic screw, and the other end of live-rollers extends to in four extensible members, drive gear sets up on the other end of live-rollers, driving motor sets up on the lateral wall of swivel mount, driving screw sets up in the swivel mount, and driving screw meshes with drive gear mutually, driving motor's output runs through the lateral wall and the driving screw fixed connection of swivel mount.

8. The adjustable wind power plant of claim 2, wherein: the outer side wall of the fixed rod is provided with spiral grains.

9. The adjustable wind power plant of claim 5, wherein: and a solar panel is arranged at the top of the turnover box.

10. The adjustable wind power plant of claim 3, wherein: the upper section of the lifting screw is not provided with spiral grains.