CN113427447A - Overturning supporting device for inverter of wind driven generator - Google Patents

Abstract

A turnover supporting device for a wind driven generator inverter comprises an installation base, a rack, a turnover motor, a turnover frame body, a clamping mechanism and a supporting mechanism; the overturning motor drives the overturning frame body to overturn relative to the rack; the clamping mechanism comprises a sliding rail, a sliding clamping plate, a sliding cylinder, a gear and a rack which are arranged on the bottom of the U-shaped frame body; a workpiece clamping position is formed between the two sliding clamping plates; the supporting mechanism comprises a supporting slide rail, a sliding supporting rod and a supporting sliding cylinder; the two sliding support rods are arranged, and two ends of each sliding support rod are respectively arranged on the support sliding rails in a sliding mode through sliding connection blocks; the supporting sliding cylinder is arranged corresponding to the sliding connecting block and drives the sliding connecting block to drive the sliding supporting rod to reciprocate on the supporting sliding rail. This scheme simple structure, manufacturing, simple to operate have high flexibility, the operation is stable.

Description

Overturning supporting device for inverter of wind driven generator

Technical Field

The invention belongs to the technical field of machinery, and relates to a turnover supporting device for an inverter of a wind driven generator.

Background

With the continuous advocation of energy conservation and environmental protection, the wind driven generator inverter is widely applied as an electrical conversion device for converting direct current into alternating current. In the process of forming the wind driven generator inverter, the bottom of the inverter needs to be subjected to sheet metal installation and screw locking.

In the prior art, manual installation is performed by workers in actual operation, and for the wind driven generator inverter, the wind driven generator inverter is heavy in weight and large in size and can be turned over by several people, so that the difficulty of operation is increased, the installation efficiency is reduced, and even safety accidents can occur. For the manual work upset of facilitating, can use supporting mechanism auxiliary stay usually, and ordinary supporting mechanism is mostly fixed supporting surface, can't accomplish corresponding support to the instant dimensional change who supports the product.

Therefore, how to solve the above problems is an important research content for those skilled in the art.

Disclosure of Invention

The invention aims to provide a turnover supporting device for an inverter of a wind driven generator.

In order to solve the technical problems, the invention is realized by the following technical scheme: a turnover supporting device for a wind driven generator inverter comprises an installation base, a rack, a turnover motor, a turnover frame body, a clamping mechanism and a supporting mechanism;

the rack is arranged on the mounting base;

the overturning frame body is of a U-shaped frame body structure; two side walls of the turnover frame body are rotatably arranged on the rack; the overturning motor drives the overturning frame body to overturn relative to the rack;

the clamping mechanism comprises a sliding rail, a sliding clamping plate, a sliding cylinder, a gear and a rack which are arranged on the bottom of the U-shaped frame body; the two sliding rails are arranged on the frame bottom in parallel at a certain distance, the two gears and the two racks are arranged on the frame bottom of the turnover frame body, the two racks are respectively arranged in a manner of being oppositely meshed with the gears, the two sliding clamping plates are respectively fixedly arranged at the end parts of the two racks, the action end of the sliding cylinder is in transmission connection with the gears and drives the gears and the racks to be in meshing transmission, and the two sliding clamping plates are driven to move oppositely or oppositely along the sliding rails; a workpiece clamping position is formed between the two sliding clamping plates;

the supporting mechanism comprises a supporting slide rail, a sliding supporting rod and a supporting sliding cylinder; the two support slide rails are symmetrically and fixedly arranged on two side walls of the turnover frame body; the number of the sliding support rods is two, and two ends of each sliding support rod are arranged on the support slide rails in a sliding mode through sliding connection blocks; the supporting sliding cylinder is arranged corresponding to the sliding connecting block and drives the sliding connecting block to drive the sliding supporting rod to reciprocate on the supporting sliding rail; the sliding support rod comprises a first sliding support rod and a second sliding support rod; two sliding support blocks are arranged on the first sliding support rod, and two support blocks are arranged on the second sliding support rod at a distance; the sliding support block on the first sliding support rod and the support block on the second sliding support rod are matched with each other to form a workpiece support position.

Furthermore, universal wheels are arranged below the mounting base.

Furthermore, the clamping mechanism further comprises two limiting buffer blocks, the two limiting buffer blocks are arranged on the motion path of the sliding clamping plate, and a workpiece clamping position is formed between the two sliding clamping plates.

Further, the turnover frame body is driven by the turnover motor to turn over 90 degrees relative to the installation base.

Furthermore, a connecting stay bar is arranged at the U-shaped opening end of the turnover frame body.

Furthermore, the supporting slide rail is fixed on the side wall of the turnover frame body through a bearing strip; the supporting sliding cylinder is fixedly arranged on the bearing strip through a floating joint. The number of the supporting sliding cylinders is four, and the supporting sliding cylinders correspond to the four sliding connecting blocks. The bearing strip is provided with a plurality of positioning pin holes at intervals along the length direction. The supporting sliding cylinder drives the sliding connecting block to drive the sliding supporting rod to slide along the sliding rail, so that the lifting of the whole supporting mechanism is adjusted. The floating joint can solve the locking condition caused by different actions of four supporting sliding cylinders when the integral supporting mechanism rises.

Furthermore, two limiting grooves are also formed in the first sliding support rod; the position of the limiting groove can be adjusted according to the size of the product to be processed; the limiting groove is used for limiting the position of the sliding support block on the first sliding support rod.

Furthermore, the support slide rail is provided with magnetic positioning pins corresponding to the sliding blocks. The magnetic positioning pin is matched with the positioning pin hole on the bearing strip, so that the magnetic positioning pin can be used as a positioning mechanism of the first sliding support rod and the second sliding support rod;

furthermore, the sliding support block comprises a product contact block and a sliding sleeve block, and the sliding sleeve block is sleeved on the first sliding support rod and is locked and fixed on the first sliding support rod through a butterfly nut; the sliding support block is also provided with a product sensor corresponding to the product contact block; the sliding sleeve block is also provided with a top bead. The sliding support block can slide left and right on the first sliding support rod.

Furthermore, clamping mechanism still includes prevents weighing down the backing plate and prevents weighing down the cylinder, prevent weighing down the cylinder setting and be in the bottom of upset framework, prevent weighing down the backing plate setting and be in the top of slip grip block, prevent weighing down the effect end of cylinder and act on prevent weighing down the backing plate, at the perpendicular to reciprocating motion is in the direction of upset framework bottom.

Furthermore, the sliding connection block is used as a first sliding support rod, a second sliding support rod and a connecting piece between the sliding rails, and the sliding connection block is provided with a groove, so that the installation is convenient and the precision is ensured.

Further, the supporting block is used for playing a role of buffering when contacting with the product, and the appearance and the size of the supporting block can be changed according to actual conditions.

The invention has the following beneficial effects:

the invention has simple structure, convenient manufacture and installation, high flexibility and stable operation. When this device can fix a position the magnetism locating pin in the locating pin hole of different positions departments on the bearing strip, this positioning mechanism can in time change whole supporting mechanism's support plane size, has solved the unchangeable situation of ordinary platform holding surface, supports the slip cylinder when different positions, has solved ordinary supporting mechanism platform and has supported and can only lead to a planar problem. When the sliding support block slides left and right, the flatness of the supporting mechanism platform can be changed in time. Has prominent substantive features and remarkable progress.

Drawings

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

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic top view of the present invention;

FIG. 3 is a schematic view of the present invention in a configuration in which the inverter of the wind power generator is built;

FIG. 4 is a schematic structural view of the clamping mechanism of the present invention clamping the inverter of the wind turbine;

FIG. 5 is a schematic structural diagram of the turnover frame body of the present invention after driving the inverter of the wind driven generator to turn over;

FIG. 6 is a schematic structural view of the support mechanism of the present invention during abduction;

FIG. 7 is a schematic view of the structure of the present invention in which the sliding support block supports the product when the product is inserted;

FIG. 8 is a schematic structural diagram of the present invention after the installation and when the sliding support block needs to be removed for abduction.

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. 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.

As shown in the figures 1-8 of the drawings,

a turnover supporting device for a wind driven generator inverter comprises an installation base 1, a rack 2, a turnover motor 3, a turnover frame 4, a clamping mechanism and a supporting mechanism;

the frame 2 is arranged on the mounting base 1; and universal wheels 24 are arranged below the mounting base 1.

The overturning frame body 4 is of a U-shaped frame body structure; two side walls of the turnover frame body 4 are rotatably arranged on the rack 2; the overturning motor 3 drives the overturning frame body 4 to overturn relative to the rack 2; the turnover frame body 4 is driven by the turnover motor 3 to turn over 90 degrees relative to the installation base 1. And a connecting support rod 17 is arranged at the U-shaped opening end of the turnover frame body 4.

The clamping mechanism comprises a sliding rail 5 arranged on the frame bottom 41 of the U-shaped frame body, a sliding clamping plate 6, a sliding cylinder 7, a gear 8 and a rack 9; the two sliding rails 5 are arranged on the frame bottom 41 in parallel at intervals, the two gears 8 and the two racks 9 are arranged on the frame bottom 41 of the turnover frame body 4, the two racks 9 are respectively arranged to be opposite to and meshed with the gears 8, the two sliding clamping plates 6 are respectively fixedly arranged at the end parts of the two racks 9, the action end of the sliding cylinder 7 is in transmission connection with the gears 8 and drives the gears 8 to be in meshing transmission with the racks 9, and the two sliding clamping plates 6 are driven to move oppositely or oppositely along the sliding rails 5; a workpiece clamping position is formed between the two sliding clamping plates 6; and the acting surface of the sliding clamping plate 6 is provided with anti-skid convex ribs. The clamping mechanism further comprises two limiting buffer blocks 18, and the two limiting buffer blocks 18 are arranged on the motion path of the sliding clamping plate 6. Clamping mechanism still includes prevents weighing down backing plate 23 and prevents weighing down the cylinder (not shown in the figure), prevent weighing down the cylinder setting and be in the bottom of upset framework 4, prevent weighing down backing plate 23 and set up the top of slip grip block 6, the effect end that prevents weighing down the cylinder acts on prevent weighing down backing plate 23, at the perpendicular to reciprocating motion is made in the direction of upset framework 4 bottom.

The supporting mechanism comprises a supporting slide rail 10, a sliding supporting rod and a supporting sliding cylinder 11; the two support slide rails 10 are symmetrically and fixedly arranged on two side walls of the turnover frame body 4; the number of the sliding support rods is two, and two ends of each sliding support rod are respectively arranged on the support slide rails 10 in a sliding manner through sliding connection blocks 12; the supporting sliding cylinder 11 is arranged corresponding to the sliding connection block 12 and drives the sliding connection block 12 to drive the sliding support rod to reciprocate on the supporting slide rail 10; the sliding support rods comprise a first sliding support rod 13 and a second sliding support rod 14; two sliding support blocks 15 are arranged on the first sliding support rod 13, and two support blocks 16 are arranged on the second sliding support rod 14 at intervals; the sliding support block 15 on the first sliding support rod 13 and the support block 16 on the second sliding support rod 14 cooperate with each other to form a workpiece support position. The sliding support block 15 is used for buffering when contacting with a product, and the appearance and size thereof can be changed according to actual conditions. The sliding connection block 12 serves as a connecting piece between the first sliding support rod 13 and the second sliding support rod 14 and the support slide rail 10, and a groove (not shown in the figure) is formed in the sliding connection block 12, so that the installation is convenient and the precision is guaranteed. The first sliding support rod 13 is also provided with two limiting grooves; the position of the limiting groove (not shown in the figure) can be adjusted according to the size of the product to be processed; the limiting groove is used for limiting the position of the sliding support block 15 on the first sliding support rod 13.

The supporting slide rail 10 is fixed on the side wall of the turnover frame body 4 through a bearing strip 18; the supporting sliding cylinder 11 is fixed on the bearing strip 18 through a floating joint 19. The number of the supporting sliding cylinders 11 is four, and the supporting sliding cylinders are arranged corresponding to the four sliding connection blocks 12. The bearing strip 18 is provided with a plurality of positioning pin holes 25 at intervals along the length direction. The supporting sliding cylinder 11 drives the sliding connecting block 12 to drive the sliding supporting rod to slide along the supporting sliding rail 10, so as to adjust the lifting of the whole supporting mechanism. The floating joint 19 can solve the locking condition caused by different actions of the four supporting sliding cylinders 11 when the integral supporting mechanism ascends.

A magnetic positioning pin 21 is further arranged on the support slide rail 10 corresponding to each slide connecting block 12. The magnetic positioning pin 21 is used to match with the positioning pin hole 25 on the bearing bar 20, so that the magnetic positioning pin (not shown in the figure) can be used as a positioning mechanism for the first sliding support bar 13 and the second sliding support bar 14;

the sliding support block 15 comprises a product contact block 151 and a sliding sleeve block 152, and the sliding sleeve block 152 is sleeved on the first sliding support rod 13 and is locked and fixed on the first sliding support rod 13 through a butterfly nut 22; a product sensor 153 is further arranged on the sliding support block 15 corresponding to the product contact block 151; the sliding sleeve block 152 is further provided with a top bead (not shown). The slide support block 15 can slide left and right on the first slide support bar 13.

When the anti-falling air cylinder works, the machine table is reset, at the moment, the turnover frame body is in a horizontal position, the clamping mechanism is reset, and the anti-falling air cylinder contracts; the first sliding support rod and the second sliding support rod adjust the distance and position on the support slide rail according to the size of the wind driven generator inverter to be processed; meanwhile, according to the structural characteristics of the wind driven generator inverter, the sliding support block moves to the position of the limiting groove for positioning;

then, a wind driven generator inverter to be processed and locked is placed; at the moment, the sliding cylinder is started to drive the two sliding clamping plates to slide to the two sides of the wind driven generator inverter and clamp the two sliding clamping plates, and the anti-falling cylinder is opened to push out the anti-falling base plate; the sliding support block supports the bottom of the wind driven generator inverter; after the inverter of the wind driven generator is clamped, starting a turnover motor to drive the turnover frame body to turn over for 90 degrees until the turnover frame body is in a vertical position; at the moment, the supporting sliding cylinder is started to drive the first sliding supporting rod and the second sliding supporting rod to respectively move downwards and upwards along the supporting sliding rail; meanwhile, the sliding supporting blocks on the first sliding supporting rod move towards the left side and the right side; avoiding a to-be-locked position of the wind power generator inverter; after the sheet metal part at the bottom of the wind driven generator inverter is installed and locked, the first sliding support rod and the second sliding support rod reset, and the height difference is generated at the bottom of the product after the sheet metal part at the bottom of the wind driven generator inverter is locked, so that the sliding support blocks at the moment are still positioned on the avoidance positions at two sides of the first sliding support rod.

And starting the turnover motor again to drive the turnover frame body to turn to a horizontal position, resetting the clamping mechanism, resetting the anti-falling air cylinder, taking out the inverter of the wind driven generator, and completing one-time processing locking.

In addition, when the device can position the magnetic positioning pin in the positioning pin holes at different positions on the bearing strip, the positioning mechanism can change the size of the supporting plane of the whole supporting mechanism in time, the problem that the supporting plane of a common platform is invariable is solved, and the problem that the platform of the common supporting mechanism can only be supported on one plane when the sliding cylinder is supported at different positions is solved. When the sliding support block slides left and right, the flatness of the supporting mechanism platform can be changed in time.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. The utility model provides a aerogenerator is upset strutting arrangement for inverter which characterized in that: the turnover mechanism comprises a mounting base, a rack, a turnover motor, a turnover frame body, a clamping mechanism and a supporting mechanism;

the rack is arranged on the mounting base;

the overturning frame body is of a U-shaped frame body structure; two side walls of the turnover frame body are rotatably arranged on the rack; the overturning motor drives the overturning frame body to overturn relative to the rack;

the clamping mechanism comprises a sliding rail, a sliding clamping plate, a sliding cylinder, a gear and a rack which are arranged on the bottom of the U-shaped frame body; the two sliding rails are arranged on the frame bottom in parallel at a certain distance, the two gears and the two racks are arranged on the frame bottom of the turnover frame body, the two racks are respectively arranged in a manner of being oppositely meshed with the gears, the two sliding clamping plates are respectively fixedly arranged at the end parts of the two racks, the action end of the sliding cylinder is in transmission connection with the gears and drives the gears and the racks to be in meshing transmission, and the two sliding clamping plates are driven to move oppositely or oppositely along the sliding rails; a workpiece clamping position is formed between the two sliding clamping plates;

the supporting mechanism comprises a supporting slide rail, a sliding supporting rod and a supporting sliding cylinder; the two support slide rails are symmetrically and fixedly arranged on two side walls of the turnover frame body; the number of the sliding support rods is two, and two ends of each sliding support rod are arranged on the support slide rails in a sliding mode through sliding connection blocks; the supporting sliding cylinder is arranged corresponding to the sliding connecting block and drives the sliding connecting block to drive the sliding supporting rod to reciprocate on the supporting sliding rail; the sliding support rod comprises a first sliding support rod and a second sliding support rod; two sliding support blocks are arranged on the first sliding support rod, and two support blocks are arranged on the second sliding support rod at a distance; the sliding support block on the first sliding support rod and the support block on the second sliding support rod are matched with each other to form a workpiece support position.

2. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: and universal wheels are arranged below the mounting base.

3. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: the clamping mechanism further comprises two limiting buffer blocks, the two limiting buffer blocks are arranged on the motion path of the sliding clamping plates, and a workpiece clamping position is formed between the two sliding clamping plates.

4. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: the overturning frame body is driven by the overturning motor to overturn for 90 degrees relative to the mounting base.

5. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: and a connecting stay bar is arranged at the U-shaped opening end of the turnover frame body.

6. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: the supporting slide rail is fixed on the side wall of the turnover frame body through a bearing strip; the supporting sliding cylinder is fixedly arranged on the bearing strip through a floating joint.

7. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: two limiting grooves are further formed in the first sliding supporting rod.

8. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: and the support slide rail is also provided with magnetic positioning pins corresponding to the sliding connecting blocks.

9. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: the sliding support block comprises a product contact block and a sliding sleeve block, and the sliding sleeve block is sleeved on the first sliding support rod and is locked and fixed on the first sliding support rod through a butterfly nut; the sliding support block is also provided with a product sensor corresponding to the product contact block; the sliding sleeve block is also provided with a top bead.

10. The overturning and supporting device for the inverter of the wind driven generator as claimed in claim 1, wherein: clamping mechanism still includes prevents weighing down the backing plate and prevents weighing down the cylinder, prevent weighing down the cylinder setting and be in the bottom of upset framework, prevent weighing down the backing plate setting and be in the top of slip grip block, prevent weighing down the effect end of cylinder and act on prevent weighing down the backing plate, at the perpendicular to reciprocating motion is in the direction of upset framework bottom.

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