CN216665814U - Wind power generation device - Google Patents

Abstract

The utility model discloses a wind power generation device which comprises a wind power generation device body, wherein two mounting frames are rotatably connected to the side walls of two ends of the wind power generation device body, communicating grooves are formed in the side walls of the two mounting frames in a penetrating mode, gears are fixedly mounted on the front side walls of the two mounting frames, a driving mechanism and a driving mechanism are arranged on the wind power generation device body, the driving mechanism penetrates through the driving mechanism and is in threaded connection with the driving mechanism, the driving mechanism is meshed with the two gears, inserting rods are connected into the two mounting frames in a sliding mode, driving plates are fixedly mounted on the side walls of the two inserting rods, and the two driving plates extend into the communicating grooves in the opposite mounting frames and are in sliding connection with the communicating grooves. The wind power generation device is reasonable in structural design, can improve the stability of the wind power generation device, and avoids the situation that the normal use of the wind power generation device is influenced because strong airflow is easy to blow in strong wind weather.

Description

Wind power generation device

Technical Field

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

Background

Wind energy is a clean renewable energy source, people pay more and more attention to the development and the utilization of the wind energy, the development and the utilization of the wind energy are mainly realized through wind power generation, the wind power generation is a process of converting kinetic energy of wind into electric energy, and the basic principle is that wind power is utilized to drive blades to rotate, and a generator is driven to generate electricity through electromagnetic induction.

In the prior art, a straight rod of a wind power generation device is generally erected on the ground, then fan blades are arranged on the straight rod, the height of the wind power generation device is high, the center of gravity of the wind power generation device is unstable, and strong air flow easily blows to cause deflection in strong wind weather so as to influence normal use of the wind power generation device.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems that in the prior art, a straight rod is erected on the ground, and fan blades are arranged on the straight rod, so that the height of the straight rod is high, the center of gravity of the wind power generation device is unstable, and strong airflow is easy to blow to cause deflection in strong wind weather, so that the normal use of the wind power generation device is influenced.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a wind power generation device comprises a wind power generation device body, two mounting frames are rotatably connected with the side walls at the two ends of the wind power generation device body, communicating grooves are respectively arranged on the side walls of the two mounting frames in a penetrating way, gears are respectively and fixedly mounted on the front side walls of the two mounting frames, the wind power generation device body is provided with a driving mechanism and a driving mechanism, the driving mechanism penetrates through the driving mechanism and is in threaded connection with the driving mechanism, the driving mechanism is meshed with the two gears, the two inserting rods are connected to the inside of the installing frame in a sliding mode, the driving plates are fixedly mounted on the side walls of the inserting rods and extend into the communicating grooves in the opposite installing frame and are connected with the installing frame in a sliding mode, the adsorbing mechanisms are arranged between the tops of the inserting rods and the inner tops of the opposite installing frame, and the reinforcing mechanisms are arranged on the two inserting rods.

Preferably, the driving mechanism comprises a servo motor fixedly installed in the wind power generation device body, a first threaded rod is fixedly installed at the tail end of an output shaft of the servo motor, and the first threaded rod is rotatably connected with the wind power generation device body.

Preferably, the driving mechanism comprises a first threaded sleeve slidably connected to the wind power generation device body, the first threaded rod penetrates through the first threaded sleeve and is in threaded connection with the first threaded sleeve, fixing rods are fixedly mounted on the side walls of the two ends of the first threaded sleeve respectively, the fixing rods are slidably connected with the wind power generation device body respectively, racks are fixedly mounted on the end portions of the fixing rods respectively, and the racks are meshed with the opposite gears.

Preferably, the adsorption mechanism comprises a first magnetic block fixedly mounted on the inner top of the mounting frame, a second magnetic block is fixedly mounted on the top of the insertion rod, and the top of the second magnetic block is opposite to the bottom magnetic pole of the first magnetic block.

Preferably, strengthening mechanism is including seting up spout and two mounting grooves on the inserted bar, the lateral wall of inserted bar rotates and is connected with the dwang, the dwang is located the outer one end tip fixed mounting of inserted bar and has the nut, the dwang is located the one end tip fixed mounting of inserted bar has first bevel gear, the spout internal rotation is connected with the second threaded rod, the top fixed mounting of second threaded rod has second bevel gear, second bevel gear meshes with first bevel gear mutually, two all be equipped with slide mechanism in the mounting groove, sliding connection has second threaded sleeve in the spout, the second threaded rod runs through second threaded sleeve and rather than threaded connection, the equal fixed mounting in second threaded sleeve's both ends lateral wall has the bution pole, two the bution pole all extends to in the relative slide mechanism and offsets rather than the inner wall.

Preferably, slide mechanism includes the anchor strut of sliding connection in the mounting groove, the chute has been seted up on the anchor strut, fixedly connected with spring between the lateral wall of anchor strut and the inside wall of mounting groove, support in the pole extends to the chute on the relative anchor strut and offsets with its inner wall.

Compared with the prior art, the utility model has the beneficial effects that:

1. through installing frame, gear, inserted bar, driving plate, actuating mechanism's setting, its stability that can improve the wind power generation set body avoids it in strong wind weather, and powerful air current blows easily and leads to it crooked, and the condition that influences its normal use takes place.

2. Through the setting of strengthening mechanism, it can improve the stability of being connected between inserted bar and the ground, has further improved the stability of wind power generation set body.

In conclusion, the wind power generation device is reasonable in structural design, the stability of the wind power generation device can be improved, and the situation that the normal use of the wind power generation device is influenced because strong airflow is easy to blow in strong wind weather is avoided.

Drawings

FIG. 1 is a schematic structural view of a wind power generation apparatus according to the present invention;

FIG. 2 is an enlarged view of the structure at A in FIG. 1;

FIG. 3 is an enlarged view of the structure at B in FIG. 1;

fig. 4 is an enlarged view of the structure at C in fig. 1.

In the figure: the wind power generation device comprises a wind power generation device body 1, a servo motor 2, a first threaded rod 3, a first threaded sleeve 4, a rack 5, a mounting frame 6, a gear 7, a first magnetic block 8, a second magnetic block 9, an inserted rod 10, a driving plate 11, a rotating rod 12, a first bevel gear 13, a second threaded rod 14, a second bevel gear 15, a sliding groove 16, a mounting groove 17, a second threaded sleeve 18, a resisting rod 19, a spring 20 and a reinforcing rod 21.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-4, a wind power generation device comprises a wind power generation device body 1, two installation frames 6 are rotatably connected to the side walls of the two ends of the wind power generation device body 1, communicating grooves are formed in the side walls of the two installation frames 6, gears 7 are fixedly installed on the front side walls of the two installation frames 6, a driving mechanism and a driving mechanism are arranged on the wind power generation device body 1, the driving mechanism comprises a servo motor 2 fixedly installed in the wind power generation device body 1, a first threaded rod 3 is fixedly installed at the tail end of an output shaft of the servo motor 2, the first threaded rod 3 is rotatably connected with the wind power generation device body 1, the stability of the wind power generation device body 1 can be improved through the installation frames 6, the gears 7, an inserted rod 10, a driving plate 11 and the driving mechanism, and the situation that the wind power generation device body 1 is prone to deflection caused by strong air flow in strong wind weather can be avoided, conditions that affect its normal use occur;

the driving mechanism penetrates through the driving mechanism and is in threaded connection with the driving mechanism, the driving mechanism is meshed with the two gears 7, the driving mechanism comprises a first threaded sleeve 4 which is connected to the wind power generation device body 1 in a sliding mode, a first threaded rod 3 penetrates through the first threaded sleeve 4 and is in threaded connection with the first threaded sleeve 4, fixing rods are fixedly mounted on the side walls of two ends of the first threaded sleeve 4, the two fixing rods are connected with the wind power generation device body 1 in a sliding mode, racks 5 are fixedly mounted at the end portions of the two fixing rods, and the two racks 5 are meshed with the opposite gears 7;

inserting rods 10 are connected in the two mounting frames 6 in a sliding mode, driving plates 11 are fixedly mounted on the side walls of the two inserting rods 10, the two driving plates 11 extend into the communicating grooves in the opposite mounting frames 6 and are connected with the communicating grooves in a sliding mode, adsorption mechanisms are arranged between the tops of the two inserting rods 10 and the inner tops of the opposite mounting frames 6 and comprise first magnetic blocks 8 fixedly mounted on the inner tops of the mounting frames 6, second magnetic blocks 9 are fixedly mounted on the tops of the inserting rods 10, and the top of each second magnetic block 9 is opposite to the bottom magnetic pole of the corresponding first magnetic block 8;

the two insert rods 10 are respectively provided with a reinforcing mechanism, the reinforcing mechanism comprises a chute 16 and two mounting grooves 17 which are arranged on the insert rods 10, the side walls of the insert rods 10 are rotatably connected with a rotating rod 12, the end part of one end of the rotating rod 12, which is positioned outside the insert rods 10, is fixedly provided with a nut, the end part of one end of the rotating rod 12, which is positioned inside the insert rods 10, is fixedly provided with a first bevel gear 13, the chute 16 is rotatably connected with a second threaded rod 14, the top end of the second threaded rod 14 is fixedly provided with a second bevel gear 15, the second bevel gear 15 is meshed with the first bevel gear 13, two mounting grooves 17 are respectively provided with a sliding mechanism, the sliding mechanism comprises a reinforcing rod 21 which is slidably connected inside the mounting groove 17, the reinforcing rod 21 is provided with a chute, a spring 20 is fixedly connected between the side wall of the reinforcing rod 21 and the inner side wall of the mounting groove 17, and the supporting rod 19 extends into the chute on the opposite reinforcing rod 21 and is abutted against the inner wall thereof, sliding connection has second threaded sleeve 18 in the spout 16, and second threaded rod 14 runs through second threaded sleeve 18 and rather than threaded connection, and the equal fixed mounting in both ends lateral wall of second threaded sleeve 18 has to support the pole 19, and two are supported the pole 19 and all extend to in the relative slide mechanism and offset rather than the inner wall, and through strengthening mechanism's setting, it can improve the stability of being connected between inserted bar 10 and the ground, has further improved the stability of wind power generation set body 1.

The utility model can be illustrated by the following operating modes:

after the wind power generation device body 1 is fixed on the ground, the servo motor 2 is started, the servo motor 2 drives the first threaded rod 3 to rotate, when the first threaded rod 3 rotates, the first threaded sleeve 4 is driven to slide downwards, when the first threaded sleeve 4 slides downwards, the two racks 5 are driven to slide downwards, the two racks 5 drive the two mounting frames 6 to rotate towards the direction far away from the side wall of the wind power generation device body 1 through the gears 7 meshed with the two racks 5, after the mounting frames 6 incline to a proper angle, the driving plate 11 is pulled, the driving plate 11 drives the inserted link 10 to slide downwards, the second magnetic block 9 on the inserted link 10 is separated from the adsorption of the first magnetic block 8, when the bottom end of the inserted link 10 is abutted against the ground, an operator uses an iron hammer to drive the driving plate 11, the bottom end of the inserted link 10 is driven to be inserted into the ground through the driving plate 11, then an operator uses a wrench to drive the nut on the rotating rod 12 to rotate, the nut drives the first bevel gear 13 on the dwang 12 to rotate, the first bevel gear 13 drives the second threaded rod 14 to rotate through the second bevel gear 15 meshed with the first bevel gear, when the second threaded rod 14 rotates, the second threaded sleeve 18 is driven to slide downwards, when the second threaded sleeve 18 slides downwards, the supporting rod 19 on the second threaded sleeve 18 gradually slides into the chute on the reinforcing rod 21 and extrudes the reinforcing rod 21 to slide out from the mounting groove 17, and the reinforcing rod 21 is inserted into soil.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (6)

1. A wind power generation device comprises a wind power generation device body (1) and is characterized in that two mounting frames (6) are rotatably connected to the side walls of the two ends of the wind power generation device body (1), communicating grooves are formed in the side walls of the two mounting frames (6) in a penetrating mode, gears (7) are fixedly mounted on the front side walls of the two mounting frames (6), a driving mechanism and a driving mechanism are arranged on the wind power generation device body (1), the driving mechanism penetrates through the driving mechanism and is in threaded connection with the driving mechanism, the driving mechanism is meshed with the two gears (7), inserting rods (10) are slidably connected in the two mounting frames (6), driving plates (11) are fixedly mounted on the side walls of the two inserting rods (10), and the two driving plates (11) extend into the communicating grooves in the opposite mounting frames (6) and are in sliding connection with the driving plates, and an adsorption mechanism is arranged between the top of each of the two insertion rods (10) and the inner top of the corresponding mounting frame (6), and a reinforcing mechanism is arranged on each of the two insertion rods (10).

2. A wind power plant as claimed in claim 1, characterized in that the driving mechanism comprises a servo motor (2) fixedly mounted in the wind power plant body (1), a first threaded rod (3) is fixedly mounted at the end of an output shaft of the servo motor (2), and the first threaded rod (3) is rotatably connected with the wind power plant body (1).

3. The wind power generation device according to claim 2, wherein the driving mechanism comprises a first threaded sleeve (4) slidably connected to the wind power generation device body (1), the first threaded rod (3) penetrates through the first threaded sleeve (4) and is in threaded connection with the first threaded sleeve, fixed rods are fixedly mounted on side walls of two ends of the first threaded sleeve (4), the two fixed rods are slidably connected with the wind power generation device body (1), racks (5) are fixedly mounted on ends of the two fixed rods, and the two racks (5) are engaged with opposite gears (7).

4. A wind power plant according to claim 1, wherein the suction mechanism comprises a first magnet (8) fixedly mounted on the inner top of the mounting frame (6), a second magnet (9) is fixedly mounted on the top of the insertion rod (10), and the top of the second magnet (9) has a magnetic pole opposite to the bottom of the first magnet (8).

5. The wind power generation device according to claim 1, wherein the reinforcing mechanism comprises a sliding groove (16) and two mounting grooves (17) formed on the inserted link (10), the side wall of the inserted link (10) is rotatably connected with a rotating rod (12), the end part of the rotating rod (12) located outside the inserted link (10) is fixedly provided with a nut, the end part of the rotating rod (12) located inside the inserted link (10) is fixedly provided with a first bevel gear (13), the sliding groove (16) is rotatably connected with a second threaded rod (14), the top end of the second threaded rod (14) is fixedly provided with a second bevel gear (15), the second bevel gear (15) is engaged with the first bevel gear (13), two sliding mechanisms are arranged in the mounting grooves (17), and the sliding groove (16) is slidably connected with a second threaded sleeve (18), the second threaded rod (14) penetrates through the second threaded sleeve (18) and is in threaded connection with the second threaded sleeve, the side walls of the two ends of the second threaded sleeve (18) are fixedly provided with abutting rods (19), and the two abutting rods (19) extend into the opposite sliding mechanisms and abut against the inner walls of the sliding mechanisms.

6. A wind power plant according to claim 5, wherein said sliding mechanism comprises a reinforcing rod (21) slidably connected in the mounting groove (17), said reinforcing rod (21) is provided with a chute, a spring (20) is fixedly connected between the side wall of said reinforcing rod (21) and the inner side wall of the mounting groove (17), and said abutting rod (19) extends into the chute of the opposite reinforcing rod (21) and abuts against the inner wall thereof.

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