CN220428993U - Firm formula wind-powered electricity generation blade mould turning device - Google Patents

Abstract

The utility model relates to the technical field of wind power blade dies, in particular to a firm wind power blade die overturning device which comprises a bottom plate and a first vertical plate, wherein a transverse plate is arranged on the inner side of the first vertical plate, a plurality of hydraulic cylinders are fixedly connected between the transverse plate and the bottom plate, an adjusting device is arranged above the transverse plate, and an overturning device is arranged above the adjusting device. The first motor is started, the first motor is matched with the first reduction gearbox to drive the second belt pulley to rotate, the second belt pulley can drive the first belt pulley to rotate through the belt, the bidirectional screw rod can be driven to rotate through the first belt pulley, the sliding chute of the bidirectional screw rod matched transverse plate drives the two third vertical plates to move in opposite directions, the third vertical plates drive the clamping blocks to move through the second reduction gearbox and the fourth vertical plates, the clamping blocks enter the grooves of the baffle plate, the die body is fixed, the die bodies with different lengths can be fixed, and the like, so that the application range is larger, and the use effect is better.

Description

Firm formula wind-powered electricity generation blade mould turning device

Technical Field

The utility model relates to the technical field of wind power blade molds, in particular to a firm wind power blade mold overturning device.

Background

The wind driven generator is power equipment for converting wind energy into mechanical work, the mechanical work drives a rotor to rotate and finally outputs alternating current, the wind driven generator generally comprises a wind wheel, a generator, a direction regulator, a tower, a speed limiting safety mechanism, an energy storage device and other components, and in the production of accessories of the wind driven generator, such as wind driven generator blades, preparation of a blade mould before production, such as surface detection, cleaning and other working procedures are required when the blades are manufactured, so that a wind driven blade mould overturning device is required.

A wind turbine blade mold turning mechanism, such as the grant publication CN 212193831U, includes a base plate. The driving block at the inner end of the rotating shaft is inserted into the plugging driving groove at one end of the bearing box body, so that the bearing box body is driven to rotate inside the positioning ring body, the wind power blade mould in the bearing box body is turned over, the sliding sealing plate is disassembled, the mould can be cleaned, the wind power blade mould turning mechanism is used for realizing the installation and the turning of the wind power blade mould in the bearing box body through the rotating shaft, the driving block and the bearing box body, however, the wind power blades are different in style and different in length, so that the corresponding wind power blade moulds are also different in length, and therefore, the distance between the two rotating shafts, the driving block and the bearing box body cannot be adjusted, and the wind power blade moulds with different lengths cannot be fixed and turned over, so that the wind power blade mould turning mechanism is small in application range and poor in use effect.

Disclosure of Invention

The utility model aims to solve the problem that the wind power generation blade mould turnover mechanism in the above-mentioned comparison patent cannot adjust the distance between two rotating shafts and the driving block and the bearing box body, and is not suitable for fixing and turnover of wind power generation blade moulds with different lengths.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a firm formula wind-powered electricity generation blade mould turning device, includes bottom plate and first riser, the top both ends rigid coupling of bottom plate has first riser, the diaphragm is installed to the inboard of first riser, and the left and right sides outer wall of diaphragm and the spout department inner wall clearance fit of first riser, the rigid coupling has a plurality of pneumatic cylinders between diaphragm and the bottom plate, adjusting device is installed to the top of diaphragm, and turning device is installed to adjusting device's top.

Preferably, the adjusting device comprises a second vertical plate, the lower part of the second vertical plate is fixedly connected with the transverse plate, the inner side of the second vertical plate is rotationally connected with a bidirectional screw, the middle outer wall of the bidirectional screw is fixedly connected with a first belt pulley, the lower part of the first belt pulley is rotationally connected with a second belt pulley through a belt, the outer wall of the belt is in clearance fit with the inner wall of a through hole of the transverse plate, the right side of the second belt pulley is connected with a first reduction gearbox, and the upper part of the first reduction gearbox is fixedly connected with the transverse plate.

Preferably, the right side of the first reduction gearbox is connected with a first motor, the middle outer wall of the first motor is fixedly connected with a first machine base, and the left side of the first machine base is fixedly connected with the first reduction gearbox.

Preferably, the turning device comprises a third vertical plate, the lower outer wall of the third vertical plate is in clearance fit with the inner wall of the chute of the transverse plate, the inside of the third vertical plate is connected with the outer wall threads of the bidirectional screw rod, a second reduction gearbox is fixedly connected above the outer side of the third vertical plate, an output shaft of the second reduction gearbox is rotationally connected with the third vertical plate through a bearing, a fourth vertical plate is fixedly connected with the output shaft of the second reduction gearbox, a plurality of clamping blocks are fixedly connected on the inner side of the fourth vertical plate, a baffle is mounted on the outer wall of each clamping block, the inner wall of the groove of each baffle is in clearance fit with the outer wall of each clamping block, and a die body is fixedly connected on the inner side of each baffle.

Preferably, a second motor is connected below the second reduction gearbox.

Preferably, a second machine seat is fixedly connected to the middle outer wall of the second motor, and the upper part of the second machine seat is fixedly connected with a second reduction gearbox.

The utility model provides a firm wind power blade mould overturning device, which has the beneficial effects that: can remove the mould body to the top centre of diaphragm through overhead hoist, afterwards start first motor, make first motor cooperation first reducing gear box drive the second belt pulley and rotate, the second belt pulley passes through the belt and can drive first belt pulley and rotate, just so can drive two third risers through first belt pulley and rotate, make the spout of two third risers cooperation diaphragm drive the fixture block through second reducing gear box and fourth riser and remove, make the fixture block enter into the recess of baffle, fix the mould body, just so can fix the operation such as being of mould body of different length, thereby application scope is bigger, the result of use is better, afterwards start the second motor, make second motor cooperation second reducing gear box drive the fourth riser and rotate, like this fourth riser just can drive the mould body through fixture block and baffle and rotate, thereby realize firm wind power generation blade mould upset.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a plan cross-sectional view of FIG. 1;

FIG. 3 is a schematic view of the first reduction gearbox, first motor and belt of FIG. 2;

FIG. 4 is a schematic view of the structure of the bi-directional screw, the second riser and the second motor of FIG. 2;

fig. 5 is a schematic view of the structure of the mold body, the fourth riser and the latch in fig. 2.

In the figure: 1. the device comprises a bottom plate, 2, a first vertical plate, 3, an adjusting device, 301, a second vertical plate, 302, a bidirectional screw, 303, a first belt pulley, 304, a belt, 305, a second belt pulley, 306, a first reduction gearbox, 4, a turnover device, 401, a third vertical plate, 402, a second reduction gearbox, 403, a fourth vertical plate, 404, a clamping block, 405, a baffle plate, 406, a die body, 4A1, a diagonal bar, 5, a transverse plate, 6, a hydraulic cylinder, 7, a first motor, 8, a first base, 9, a second motor, 10 and a second base.

The specific embodiment is as follows:

the utility model is further described below with reference to the accompanying drawings:

example 1:

referring to fig. 1-5, in this embodiment, a firm wind power blade mold turning device includes a bottom plate 1 and a first vertical plate 2, wherein two ends of the upper side of the bottom plate 1 are fixedly connected with the first vertical plate 2, a chute is processed on the inner side of the first vertical plate 2, a transverse plate 5 is installed on the inner side of the first vertical plate 2, an opening and 2 chutes are processed on the upper side of the transverse plate 5, the outer walls of the left side and the right side of the transverse plate 5 are in clearance fit with the inner walls of the chute of the first vertical plate 2, 2 hydraulic cylinders 6 are fixedly connected between the transverse plate 5 and the bottom plate 1, the type of each hydraulic cylinder 6 can be selected according to the requirements of a user, the transverse plate 5 and other heights can be driven to move through the hydraulic cylinders 6, an adjusting device 3 is installed on the upper side of the transverse plate 5, and a turning device 4 is installed on the upper side of the adjusting device 3.

Referring to fig. 1-4, an adjusting device 3 comprises a second vertical plate 301, a bidirectional screw 302, a first belt pulley 303, a belt 304, a second belt pulley 305 and a first reduction gearbox 306, wherein the lower parts of the left and right second vertical plates 301 are fixedly connected with a transverse plate 5, the bidirectional screw 302 is rotationally connected to the inner side of the second vertical plate 301, the first belt pulley 303 is fixedly connected to the middle outer wall of the bidirectional screw 302, the second belt pulley 305 is rotationally connected to the lower part of the first belt pulley 303 through the belt 304, the outer wall of the belt 304 is in clearance fit with the inner wall of a through hole of the transverse plate 5, the right side of the second belt pulley 305 is connected with the first reduction gearbox 306, the upper part of the first reduction gearbox 306 is fixedly connected with the transverse plate 5, the right side of the first reduction gearbox 306 is connected with a first motor 7, the first reduction gearbox 306 and the type of the first motor 7 can be selected according to the requirements of users, the first motor 7 is matched with the first reduction gearbox 306 to drive the second belt pulley 305 to rotate stably, the middle outer wall of the first motor 7 is fixedly connected with a first stand 8, and the left side of the first stand 8 is fixedly connected with the first reduction gearbox 306;

the die body 406 can be moved to the middle above the transverse plate 5 through the lifting device, then an external power supply of the first motor 7 is connected, the first motor 7 is started, the first motor 7 is matched with the first reduction gearbox 306 to drive the second belt pulley 305 to rotate, the second belt pulley 305 can drive the first belt pulley 303 to rotate through the belt 304, the bidirectional screw 302 can be driven to rotate through the first belt pulley 303, the bidirectional screw 302 is matched with the sliding chute of the transverse plate 5 to drive the two third vertical plates 401 to move in opposite directions, the third vertical plates 401 drive the clamping blocks 404 to move through the second reduction gearbox 402 and the fourth vertical plates 403, the clamping blocks 404 enter the grooves of the baffle 405, the die body 406 is fixed, and the die body 406 with different lengths can be fixed.

Referring to fig. 1, 2, 4 and 5, the turning device 4 includes a third riser 401, a second reduction gearbox 402, a fourth riser 403, a clamping block 404, a baffle 405 and a die body 406, the lower outer walls of the left and right third risers 401 are in clearance fit with the inner walls of the sliding grooves of the transverse plates 5, the inside of the third riser 401 is connected with the outer walls of the bidirectional screw 302 through threads, a second reduction gearbox 402 is fixedly connected above the outer sides of the third risers 401, the model of the second reduction gearbox 402 can be selected according to the requirements of a user, an output shaft of the second reduction gearbox 402 is rotationally connected with the third riser 401 through a bearing, the output shaft of the second reduction gearbox 402 is fixedly connected with the fourth riser 403, the inner sides of the left and right fourth risers 403 are fixedly connected with 2 clamping blocks 404, the outer walls of the clamping blocks 404 are provided with the baffle 405, the outer sides of the baffle 405 are provided with grooves, the inner walls of the grooves of the baffle 405 are in clearance fit with the outer walls of the clamping blocks 404, the die body 406 is fixedly connected with a blade die, the lower side of the second reduction gearbox 402 is fixedly connected with a second motor 9, the second motor 9 can be fixedly connected with the second motor 9 according to the requirements of the second motor 9, and the requirements of the second base is fixedly connected with the second base 10;

the external power supply of the second motor 9 is connected, the second motor 9 is started, the second motor 9 is matched with the second reduction gearbox 402 to drive the fourth vertical plate 403 to rotate, and therefore the fourth vertical plate 403 can drive the die body 406 to rotate through the clamping blocks 404 and the baffle 405, and the stable overturning of the wind power generation blade die is achieved.

In this embodiment, when an operator needs to use the firm wind power blade mold overturning device, firstly, the operator can move the mold body 406 to the middle above the transverse plate 5 through the hoisting device, then the external power supply of the first motor 7 is connected, the first motor 7 is started, the first motor 7 is matched with the first reduction gearbox 306 to drive the second belt pulley 305 to rotate, the second belt pulley 305 can drive the first belt pulley 303 to rotate through the belt 304, the bidirectional screw 302 can be driven to rotate through the first belt pulley 303, the bidirectional screw 302 is matched with the sliding groove of the transverse plate 5 to drive the two third vertical plates 401 to move in opposite directions, the third vertical plates 401 can drive the clamping blocks 404 to move through the second reduction gearbox 402 and the fourth vertical plates 403, the clamping blocks 404 can enter the grooves of the baffle 405 to fix the mold body 406, and the like, the application range is larger, the external power supply of the second motor 9 is connected, the second motor 9 is started to drive the second reduction gearbox 402 to drive the fourth vertical plates 403 to rotate, and the fourth vertical plates 403 can rotate through the fourth vertical plates 403 to realize firm rotation of the mold body 405, and firm wind power overturning of the mold body 405 is realized.

Example 2:

referring to fig. 1-5, in this embodiment, the present utility model provides a technical solution: the turning device 4 can also comprise inclined rods 4A1, and the outer walls at two ends of the left and right inclined rods 4A1 are respectively fixedly connected with the fourth vertical plate 403 and the outer wall of the output shaft of the second reduction gearbox 402;

4 diagonal rods 4A1 may be disposed on the outer wall of the output shaft of the second reduction gearbox 402, and the other end of the diagonal rod 4A1 is connected to the fourth riser 403, so that stability of the output shaft of the second reduction gearbox 402 and the fourth riser 403 may be improved through the diagonal rod 4 A1.

In this embodiment, when the operator needs to use the stable wind power blade mold turning device, 4 diagonal rods 4A1 are disposed on the outer wall of the output shaft of the second reduction gearbox 402, and the other end of the diagonal rod 4A1 is connected to the fourth riser 403, so that the stability of the output shaft of the second reduction gearbox 402 and the stability of the fourth riser 403 can be improved through the diagonal rod 4 A1.

While the utility model has been shown and described with reference to a preferred embodiment, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the utility model.

Claims (6)

1. The utility model provides a firm wind-powered electricity generation blade mould turning device, includes bottom plate (1) and first riser (2), the top both ends rigid coupling of bottom plate (1) has first riser (2), its characterized in that: the novel hydraulic lifting device is characterized in that a transverse plate (5) is arranged on the inner side of the first vertical plate (2), the outer walls of the left side and the right side of the transverse plate (5) are in clearance fit with the inner walls of the sliding groove of the first vertical plate (2), a plurality of hydraulic cylinders (6) are fixedly connected between the transverse plate (5) and the bottom plate (1), an adjusting device (3) is arranged above the transverse plate (5), and a turning device (4) is arranged above the adjusting device (3).

2. The stable wind power blade mold overturning device according to claim 1, wherein: the adjusting device (3) comprises a second vertical plate (301), the lower part of the second vertical plate (301) is fixedly connected with a transverse plate (5), the inner side of the second vertical plate (301) is rotationally connected with a bidirectional screw rod (302), the middle outer wall of the bidirectional screw rod (302) is fixedly connected with a first belt pulley (303), the lower part of the first belt pulley (303) is rotationally connected with a second belt pulley (305) through a belt (304), the outer wall of the belt (304) is in clearance fit with the inner wall of a through hole of the transverse plate (5), the right side of the second belt pulley (305) is connected with a first reduction gearbox (306), and the upper part of the first reduction gearbox (306) is fixedly connected with the transverse plate (5).

3. The stable wind power blade mold turning device according to claim 2, wherein: the right side of first reducing gear box (306) is connected with first motor (7), and the middle outer wall rigid coupling of first motor (7) has first frame (8), the left side of first frame (8) is with first reducing gear box (306) looks rigid coupling.

4. The stable wind power blade mold overturning device according to claim 1, wherein: the turnover device (4) comprises a third vertical plate (401), the lower outer wall of the third vertical plate (401) is in clearance fit with the inner wall of a chute of a transverse plate (5), the inner wall of the third vertical plate (401) is in clearance fit with the outer wall of a bidirectional screw rod (302), a second reduction gearbox (402) is fixedly connected above the outer side of the third vertical plate (401), an output shaft of the second reduction gearbox (402) is rotationally connected with the third vertical plate (401) through a bearing, a fourth vertical plate (403) is fixedly connected with the output shaft of the second reduction gearbox (402), a plurality of clamping blocks (404) are fixedly connected with the inner side of the fourth vertical plate (403) left and right, a baffle (405) is mounted on the outer wall of the clamping blocks (404), the inner wall of the groove of the baffle (405) is in clearance fit with the outer wall of the clamping blocks (404), and a die body (406) is fixedly connected with the inner side of the baffle (405) left and right.

5. The stable wind power blade mold turning device according to claim 4, wherein: a second motor (9) is connected below the second reduction gearbox (402).

6. The stable wind power blade mold turning device according to claim 5, wherein: the middle outer wall of the second motor (9) is fixedly connected with a second machine seat (10), and the upper part of the second machine seat (10) is fixedly connected with a second reduction gearbox (402).