CN217943975U

CN217943975U - Novel turnover device for stable wind power blade mould

Info

Publication number: CN217943975U
Application number: CN202221868163.8U
Authority: CN
Inventors: 刘伟
Original assignee: Dongtai Maisheng Intelligent Technology Co ltd
Current assignee: Dongtai Maisheng Intelligent Technology Co ltd
Priority date: 2022-07-20
Filing date: 2022-07-20
Publication date: 2022-12-02
Anticipated expiration: 2032-07-20

Abstract

A novel stable wind power blade mould overturning device comprises a supporting base mechanism, an overturning arm plate, a side part driving mechanism and a middle driving mechanism; the utility model discloses lateral part actuating mechanism has been installed respectively in upset armplate both sides, actuating mechanism in the middle of intermediate position between the upset armplate has been installed, and lateral part actuating mechanism's upper and lower both ends rotate with the outside below of an outside positioning bottom plate and the outside of an upset armplate respectively and are connected, flexible drive upset armplate in upper end through lateral part actuating mechanism, the upper and lower both ends of actuating mechanism rotate respectively simultaneously and connect between two inboard positioning bottom plates and between two upset armplates in the middle of, the flexible drive in upper end through middle actuating mechanism connects between two upset armplates, so make the both sides of upset armplate and centre all obtain stable collaborative drive, make the upset armplate more steady when the upset.

Description

Novel turnover device for stable wind power blade mould

Technical Field

The utility model relates to a novel firm formula wind-powered electricity generation blade mould upset device.

Background

The mould for producing the wind driven generator blade is a very important production device in the production of the wind driven generator blade; wind power generation means converting kinetic energy of wind into electric energy; wind energy is a clean and pollution-free renewable energy source and is utilized by people for a long time; a mould is needed in the production process of the wind power generation machinery; the blade mould of the existing wind driven generator generally needs to be opened and closed, so the blade mould of the wind driven generator needs to be opened and closed through the overturning armplate, but the existing power structure for driving the overturning armplate is generally arranged on one side of the overturning armplate, so that the overturning armplate is driven very unstably.

Disclosure of Invention

To the weak point of above-mentioned prior art, the utility model provides a problem do: the utility model provides a novel steady formula wind-powered electricity generation blade mould turning device that structure is steady.

In order to solve the above problem, the utility model discloses the technical scheme who takes as follows:

a novel stable wind power blade mould overturning device comprises a supporting base mechanism, an overturning arm plate, a side part driving mechanism and a middle driving mechanism; the supporting base mechanism comprises an inner side positioning bottom plate, an outer side positioning bottom plate, a positioning pin and a bottom connecting plate strip; the two bottom connecting laths are arranged oppositely in parallel; the lower ends of the inner side positioning bottom plate and the outer side positioning bottom plate are fixedly arranged at the upper ends of the bottom connecting lathes respectively; two turnover positioning pins are respectively arranged between the outer side of the upper end of the inner positioning bottom plate and the inner side of the upper end of the outer positioning bottom plate, and two turnover arm plates are respectively rotatably sleeved on the turnover positioning pins; the outer sides of the outer side positioning bottom plates are respectively provided with a side part driving mechanism; the upper end and the lower end of the side driving mechanism are respectively rotatably connected with the lower part of the outer side of an outer side positioning bottom plate and the outer side of an overturning arm plate, and the upper end of the side driving mechanism telescopically drives the overturning arm plate; the middle driving mechanism is arranged between the two inner side positioning bottom plates and the two turnover arm plates, the upper end and the lower end of the middle driving mechanism are respectively connected between the two inner side positioning bottom plates and between the two turnover arm plates in a rotating mode, and the upper end of the middle driving mechanism is connected between the two turnover arm plates in a telescopic driving mode.

Further, the side driving mechanism comprises a side telescopic rod and a side driving cylinder body; the upper end of the side driving cylinder body is telescopically provided with a side telescopic rod; a lateral positioning pin is respectively arranged on the outer side below the outer positioning bottom plate; a lateral positioning pin is respectively arranged on the outer side surface of the turnover arm plate; the upper end of the side telescopic rod and the lower end of the side driving cylinder body are respectively provided with a side rotating ring body; the side part rotating ring body at the upper end of the side part telescopic rod is rotatably sleeved on the side part positioning pin on the outer side surface of the turnover arm plate; the side part rotating ring body at the lower end of the side part driving cylinder body is rotatably sleeved on the side part positioning pin of the outer side positioning bottom plate.

Further, the middle driving mechanism comprises a middle telescopic rod and a middle driving cylinder body; the upper end of the middle driving cylinder body is telescopically provided with a middle telescopic rod; a middle positioning pin is arranged between the two inner positioning bottom plates; a middle positioning pin is arranged between the two turnover arm plates; the upper end of the middle telescopic rod and the lower end of the middle driving cylinder body are respectively provided with a middle rotating ring body; the middle rotating ring body at the upper end of the middle telescopic rod is rotatably sleeved on the middle positioning pin between the two turnover arm plates; the middle rotating ring body at the lower end of the middle driving cylinder body is rotatably sleeved on the middle positioning pin between the two inner side positioning bottom plates.

Furthermore, the front ends of the lower parts of the inner side positioning bottom plate and the outer side positioning bottom plate are jointly provided with a reinforcing plate.

Furthermore, the outer sides of the two turnover arm plates are provided with a reinforcing plate together.

Further, the side driving mechanism and the middle driving mechanism are oil cylinders or air cylinders.

Furthermore, the turnover arm plate is of a plate body structure.

The utility model has the advantages as follows:

the utility model discloses lateral part actuating mechanism has been installed respectively in upset armplate both sides, actuating mechanism in the middle of having installed in the intermediate position between the upset armplate, and lateral part actuating mechanism's upper and lower both ends rotate with the outside below of an outside location bottom plate and the outside of an upset armplate respectively and be connected, through the flexible drive upset armplate in upper end of lateral part actuating mechanism, the upper and lower both ends of middle actuating mechanism rotate respectively simultaneously and connect between two inboard location bottom plates and between two upset armplates, the flexible drive in upper end through middle actuating mechanism connects between two upset armplates, so make the both sides and the centre of upset armplate all obtain stable collaborative drive, make more steady when the upset armplate overturns.

Drawings

Fig. 1 is a schematic structural view of the turning arm plate of the present invention.

Fig. 2 is a schematic structural view of the turning arm plate of the present invention starting to turn.

Fig. 3 is a schematic structural view of the turnover arm plate of the present invention turning over to the upper side.

Fig. 4 is a schematic perspective view of the other side of fig. 1 according to the present invention.

Fig. 5 is a schematic side view of the present invention shown in fig. 1.

Fig. 6 is a schematic side view of the structure of fig. 2 according to the present invention.

Fig. 7 is a schematic longitudinal sectional view of fig. 1 according to the present invention.

Fig. 8 is a schematic longitudinal sectional view of fig. 2 according to the present invention.

Fig. 9 is a schematic longitudinal sectional structure view of fig. 3 according to the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 9, a novel stable wind turbine blade mold turnover device comprises a support base mechanism 1, a turnover arm plate 2, a side driving mechanism 3 and a middle driving mechanism 4; the supporting base mechanism 1 comprises an inner side positioning bottom plate 13, an outer side positioning bottom plate 12, a positioning pin 14 and a bottom connecting lath 11; the two bottom connecting laths 11 are arranged, and the two bottom connecting laths 11 are oppositely arranged in parallel; the two ends of the upper sides of the two bottom connecting laths 11 are respectively provided with an inner side positioning bottom plate 13, the outer sides of the inner side positioning bottom plates 13 are respectively provided with an outer side positioning bottom plate 12, and the lower ends of the inner side positioning bottom plates 13 and the outer side positioning bottom plates 12 are respectively fixedly arranged at the upper ends of the bottom connecting laths 11; a turning positioning pin 14 is respectively arranged between the outer side of the upper end of the inner positioning bottom plate 13 and the inner side of the upper end of the outer positioning bottom plate 12, two turning arm plates 2 are arranged, and the turning positioning pins 14 are respectively sleeved with one turning arm plate 2 in a rotating mode; the outer sides of the outer side positioning bottom plates 12 are respectively provided with a side driving mechanism 3; the upper end and the lower end of the side driving mechanism 3 are respectively rotatably connected with the lower part of the outer side of an outer side positioning bottom plate 12 and the outer side of an overturning arm plate 2, and the upper end of the side driving mechanism 3 telescopically drives the overturning arm plate 2; the middle driving mechanism 4 is installed between the two inner side positioning bottom plates 13 and the two turnover arm plates 2, the upper end and the lower end of the middle driving mechanism 4 are respectively connected between the two inner side positioning bottom plates 13 and between the two turnover arm plates 2 in a rotating mode, and the upper end of the middle driving mechanism 4 is connected between the two turnover arm plates 2 in a telescopic driving mode.

As shown in fig. 1 to 9, in order to realize stable side driving, further, the side driving mechanism 3 includes a side telescopic rod 32 and a side driving cylinder 31; a lateral telescopic rod 32 is telescopically arranged at the upper end of the lateral driving cylinder 31; a lateral positioning pin 5 is respectively arranged at the lower outer side of the outer positioning bottom plate 12; a lateral positioning pin 5 is respectively arranged on the outer lateral surface of the turnover arm plate 2; the upper end of the side telescopic rod 32 and the lower end of the side driving cylinder 31 are respectively provided with a side rotating ring body 7; the side part rotating ring body 7 at the upper end of the side part telescopic rod 32 is rotatably sleeved on the side part positioning pin 5 on the outer side surface of the turnover arm plate 2; the side rotating ring body 7 at the lower end of the side driving cylinder 31 is rotatably sleeved on the side positioning pin 5 of the outer side positioning bottom plate 12.

As shown in fig. 1 to 9, in order to realize stable intermediate driving, further, the intermediate driving mechanism 4 includes an intermediate telescopic rod 42 and an intermediate driving cylinder 41; the upper end of the middle driving cylinder body 41 is telescopically provided with a middle telescopic rod 42; a middle positioning pin 6 is arranged between the two inner positioning bottom plates 13; a middle positioning pin 6 is arranged between the two turnover arm plates 2; the upper end of the middle telescopic rod 42 and the lower end of the middle driving cylinder body 41 are respectively provided with a middle rotating ring body 8; the middle rotating ring body 8 at the upper end of the middle telescopic rod 42 is rotatably sleeved on the middle positioning pin 6 between the two turnover arm plates 2; the middle rotating ring body 8 at the lower end of the middle driving cylinder 41 is rotatably sleeved on the middle positioning pin 6 between the two inner positioning bottom plates 13.

As shown in fig. 1 to 9, in order to improve the structural stability of the inner positioning bottom plate 13 and the outer positioning bottom plate 12, a reinforcing plate 9 is provided at the lower front ends of the inner positioning bottom plate 13 and the outer positioning bottom plate 12. Further, a reinforcing plate 9 is arranged on the outer sides of the two turnover arm plates 2 together. Further, the side driving mechanism 3 and the middle driving mechanism 4 are oil cylinders or air cylinders. Further, the turning arm plate 2 is of a plate body structure.

The utility model discloses lateral part actuating mechanism 3 has been installed respectively in 2 both sides of upset armplate, actuating mechanism 4 in the middle of having installed in the intermediate position between upset armplate 2, and the upper and lower both ends of lateral part actuating mechanism 3 rotate with the outside below of an outside positioning bottom plate 12 and the outside of an upset armplate 2 respectively and be connected, through the flexible drive upset armplate 3 in upper end of lateral part actuating mechanism 3, the upper and lower both ends of middle actuating mechanism 4 rotate respectively simultaneously and connect between two inboard positioning bottom plates 13 and between two upset armplates 2, the flexible drive in upper end through middle actuating mechanism 4 connects between two upset armplates 2, so make the both sides and the centre of upset armplate 2 all obtain stable collaborative drive, make upset armplate 2 more steady when the upset, lateral part actuating mechanism 3 and middle actuating mechanism 4 accessible collaborative controller drive.

The above description is only for the preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A novel stable wind power blade mould turnover device is characterized by comprising a supporting base mechanism, a turnover arm plate, a side part driving mechanism and a middle driving mechanism; the supporting base mechanism comprises an inner side positioning bottom plate, an outer side positioning bottom plate, a positioning pin and a bottom connecting plate strip; the two bottom connecting lathes are arranged oppositely and parallelly; the two ends of the upper sides of the two bottom connecting laths are respectively provided with an inner side positioning bottom plate, the outer sides of the inner side positioning bottom plates are respectively provided with an outer side positioning bottom plate, and the lower ends of the inner side positioning bottom plate and the outer side positioning bottom plate are respectively fixedly arranged at the upper ends of the bottom connecting laths; two turnover positioning pins are respectively arranged between the outer side of the upper end of the inner positioning bottom plate and the inner side of the upper end of the outer positioning bottom plate, and two turnover arm plates are respectively rotatably sleeved on the turnover positioning pins; the outer sides of the outer side positioning bottom plates are respectively provided with a side driving mechanism; the upper end and the lower end of the side driving mechanism are respectively rotatably connected with the lower part of the outer side of an outer side positioning bottom plate and the outer side of an overturning arm plate, and the upper end of the side driving mechanism telescopically drives the overturning arm plate; the middle driving mechanism is arranged between the two inner side positioning bottom plates and the two turnover arm plates, the upper end and the lower end of the middle driving mechanism are respectively connected between the two inner side positioning bottom plates and between the two turnover arm plates in a rotating mode, and the upper end of the middle driving mechanism is connected between the two turnover arm plates in a telescopic driving mode.

2. The novel stabilized wind turbine blade mold turning device as claimed in claim 1, wherein the lateral driving mechanism comprises a lateral telescopic rod and a lateral driving cylinder; the upper end of the side driving cylinder body is telescopically provided with a side telescopic rod; a lateral positioning pin is respectively arranged on the outer side below the outer positioning bottom plate; the outer side surfaces of the turnover arm plates are respectively provided with a side positioning pin; the upper end of the side telescopic rod and the lower end of the side driving cylinder body are respectively provided with a side rotating ring body; the side rotating ring body at the upper end of the side telescopic link is rotatably sleeved on the side positioning pin on the outer side surface of the turnover arm plate; the side part rotating ring body at the lower end of the side part driving cylinder body is rotatably sleeved on the side part positioning pin of the outer side positioning bottom plate.

3. The novel stable wind power blade mold turning device as claimed in claim 1, wherein the intermediate driving mechanism comprises an intermediate telescopic rod and an intermediate driving cylinder; the upper end of the middle driving cylinder body is telescopically provided with a middle telescopic rod; a middle positioning pin is arranged between the two inner positioning bottom plates; a middle positioning pin is arranged between the two turnover arm plates; the upper end of the middle telescopic rod and the lower end of the middle driving cylinder body are respectively provided with a middle rotating ring body; the middle rotating ring body at the upper end of the middle telescopic rod is rotatably sleeved on the middle positioning pin between the two turnover arm plates; the middle rotating ring body at the lower end of the middle driving cylinder body is rotatably sleeved on the middle positioning pin between the two inner side positioning bottom plates.

4. The novel stable wind power blade mold turnover device according to claim 1, wherein a reinforcing plate is jointly arranged at the front ends below the inner side positioning bottom plate and the outer side positioning bottom plate.

5. The novel stable wind power blade mold turning device as claimed in claim 1, wherein a reinforcing plate is provided on the outer side of the two turning arm plates.

6. The novel stable wind power blade mold turnover device according to claim 1, wherein the side driving mechanism and the middle driving mechanism are oil cylinders or air cylinders.

7. The novel stable wind power blade die turnover device of claim 1, wherein the turnover arm plate is of a plate body structure.