CN217191633U - Rotatable flip structure - Google Patents

Abstract

The utility model discloses a rotatable flip structure, including frame, roll-over table and actuating mechanism, actuating mechanism install extremely in the frame, the roll-over table hinge to in the frame, the roll-over table with be connected with the upset jar between the frame, it is connected with rotary mechanism to rotate on the roll-over table, actuating mechanism with connect through the connector between the rotary mechanism, the connector is including two connecting blocks of mutually supporting, the connecting block set up respectively in the roll-over table and in the frame, can connect and separate along with the rotation of roll-over table between the connecting block. The driving mechanism can drive the rotating mechanism on the overturning platform to rotate under the mutual cooperation of the connecting blocks; after the rotating mechanism finishes working, the overturning cylinder pushes the overturning platform to overturn for 90 degrees, so that the two connecting blocks are separated, the driving mechanism is separated from the rotating mechanism, and the driving mechanism does not need to be driven to act.

Description

Rotatable flip structure

Technical Field

The utility model relates to an automation equipment field, more specifically relates to a rotatable flip structure.

Background

With the development of technology, automatic equipment has gradually replaced manual work to carry out production and manufacturing, and particularly in the metallurgical industry, because of high danger, severe working environment and high labor intensity, the adoption of automation to replace manual production is more important and urgent.

In the cold rolling wire industry, wires need to be wound after cold rolling forming and then lifted to each station for processing, weighing, binding and storing, wherein equipment used in the wire winding process is a wire winder. The existing wire rod coiling machine mainly comprises a coiling drum and a driving mechanism, wherein the driving mechanism drives the coiling drum to rotate so as to realize the coiling of a wire rod. The existing coiling drums are horizontally arranged, so that a coiling mechanism can conveniently take coils and then hang the coils on coil conveying equipment. However, the horizontal type winding drum has the problem of untight winding, so that the uniform winding of the wire rod is difficult to maintain, and the quality is difficult to ensure in the subsequent production and processing processes.

The vertical coiling device is difficult to realize, mainly because the load in the coiling process of the coiling drum is large, the power of the used driving mechanism is large, if the 90-degree turnover of the coiling drum needs to be realized, a larger hydraulic cylinder needs to be equipped, the cost is greatly increased, the service life of the movably arranged driving mechanism is greatly reduced, and the equipment maintenance cost is also greatly increased. In the prior art, a connecting structure is not provided, so that the rotary transmission and the 90-degree turnover can be realized, and the vertical placement of the coiling equipment cannot be realized.

Therefore, a reversible rotation transmission mechanism is required to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel technical scheme of rotatable flip structure.

According to a first aspect of the utility model, a rotatable overturning structure is provided, which comprises a frame, an overturning platform and a driving mechanism, the driving mechanism is arranged on the frame, the top of the frame is provided with a hinged column and a supporting column, one end of the bottom of the overturning platform is hinged to the hinged column, the other end of the overturning platform is placed on the supporting column, the bottom of one end of the overturning platform close to the supporting column is hinged with an overturning cylinder, the other end of the turnover cylinder is hinged to the frame, the turnover table is rotatably connected with a rotating mechanism, the driving mechanism is connected with the rotating mechanism through a connector, the connector comprises two connecting blocks which are matched with each other, the connecting blocks are respectively arranged on the overturning platform and the rack, and can be connected and separated along with the rotation of the overturning platform; and a brake device is arranged on the driving mechanism.

Through the scheme, the driving mechanism can drive the rotating mechanism on the overturning platform to rotate under the mutual cooperation of the connecting blocks; after the rotating mechanism finishes working, the overturning cylinder pushes the overturning platform to overturn for 90 degrees, so that the two connecting blocks are separated, the driving mechanism is separated from the rotating mechanism, the driving mechanism does not need to be driven to act, the load of the overturning cylinder is reduced, the maintenance frequency of the driving mechanism is reduced, and the device is more suitable for being used in a cold-rolled wire production line with a complex working condition environment.

Preferably, the two connecting blocks are respectively a first end face gear and a second end face gear, the first end face gear is coaxially fixed to the bottom of the rotating mechanism, and the second end face gear is connected to the driving mechanism through a transmission mechanism.

Through this scheme, first terminal surface gear can realize 90 upsets along with the roll-over table to realize breaking away from and meshing with the second terminal surface gear, make it conveniently to carry out the separation and reunion and conveniently carry out rotatory drive again promptly.

Preferably, the transmission mechanism comprises a transmission shaft and a transmission gear set, the transmission shaft vertically rotates to the rack, the second end face gear is fixed to the top end of the transmission shaft, the driving mechanism drives the transmission shaft to rotate through the transmission gear set, and the transmission gear set comprises two bevel gears which are meshed with each other.

Through this scheme, drive mechanism can realize first terminal surface gear and the meshing of second terminal surface gear at vertical angle with actuating mechanism's moment of torsion vertical output, guarantees that actuating mechanism can horizontal arrangement, helps further improving actuating mechanism's life.

Preferably, the meshing teeth of the first end face gear and the second end face gear are both wedge-shaped, and the tops of the meshing teeth are both obliquely arranged.

Through this scheme, wedge-shaped meshing tooth and top slope arrange, can play the effect of direction to meshing process after the upset of first terminal surface gear, further make things convenient for the meshing of first terminal surface gear and second terminal surface gear.

Preferably, the meshing teeth of the first face gear are all inclined towards the middle shaft in a concave manner, and the second face gear is inclined towards the middle shaft in a convex manner; and slag discharge grooves are formed among the meshing teeth.

Through this scheme, make first terminal surface gear form middle concave recess shape, match each other with convex toper structure in the middle of the second terminal surface gear, not only realize the meshing more easily after the rotation, the reliability of meshing is higher moreover.

Preferably, the first end face gear and the second end face gear are provided with at least two groups of gear rings in a one-to-one correspondence mode, the gear rings are arranged in a concentric mode, and the gear rings are respectively composed of a plurality of meshing teeth.

Through this scheme, further improve the reliability of meshing, improved the quantity of meshing tooth moreover, dispersed the atress of single meshing tooth, help improving the life of connecting block.

Preferably, the driving mechanism comprises a speed reducer, and a brake device is arranged on the speed reducer.

Through this scheme, the speed reducer can keep the angle of pivot fixed under brake equipment's effect to guarantee the temporary fixation of second terminal surface gear, avoid the rotatory connecting block that causes of upset meshing in-process to damage.

According to one embodiment of the disclosure, the device not only can realize the torque vertical output of the driving mechanism and drive the rotating mechanism to rotate, but also can enable the rotating mechanism to be independently turned over so as to adapt to the requirements of different working conditions; the driving mechanism cannot be driven to synchronously act in the overturning process of the rotating mechanism, the load of the overturning lever is reduced, the driving mechanism can be ensured to be fixed in position, the service life of the driving mechanism is prolonged, and the maintenance frequency is reduced.

Other features of the present invention and advantages thereof will become apparent from the following detailed description of exemplary embodiments of the invention, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a schematic view of a rotatable turnover structure according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of the rotatable turnover structure in fig. 1 after being turned over.

Fig. 3 is a schematic view showing a process of turning and engaging two connecting blocks in fig. 1.

Fig. 4 is a schematic view showing the structure of two connection blocks in fig. 3.

Fig. 5 is a schematic top view of two connecting blocks of fig. 4.

Fig. 6 is a schematic structural view of the transmission mechanism in fig. 2.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: unless specifically stated otherwise, the relative arrangement of the components and steps, the numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present invention.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses.

Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

Examples

As shown in fig. 1 to 6, the rotatable turnover structure in this embodiment includes a frame 100, a turnover table 200 and a driving mechanism 300, the driving mechanism 300 is installed on the frame 100, the turnover table 200 is hinged to the frame 100, a turnover cylinder 110 is connected between the turnover table 200 and the frame 100, a rotating mechanism 210 is rotatably connected to the turnover table 200, the driving mechanism 300 and the rotating mechanism 210 are connected through a connector 400, the connector 400 includes two connecting blocks that are matched with each other, the connecting blocks are respectively arranged on the turnover table 200 and the frame 100, and the connecting blocks can be connected and separated with the rotation of the turnover table 200.

Through the scheme of the embodiment, the driving mechanism 300 can drive the rotating mechanism 210 on the overturning platform 200 to rotate under the mutual cooperation of the connecting blocks; after the rotating mechanism 210 finishes working, the overturning cylinder 110 pushes the overturning platform 200 to overturn for 90 degrees, so that the two connecting blocks are separated, the driving mechanism 300 is separated from the rotating mechanism 210, the driving mechanism 300 does not need to be driven to act, the load of the overturning cylinder 110 is reduced, the maintenance frequency of the driving mechanism 300 is reduced, and the device is more suitable for being used in a cold-rolled wire production line with complex working conditions and environments.

The top of the rack 100 is provided with an articulated column 121 and a supporting column 122, one end of the bottom of the overturning platform 200 is articulated on the articulated column 121, the other end of the overturning platform 200 is placed on the supporting column 122, and the overturning cylinder 110 is articulated to the bottom of one end of the overturning platform 200 close to the supporting column 122. The turnover table 200 is supported by the hinged columns 121 and the supporting columns 122, so that a space for connecting block clutching is reserved at the bottom of the turnover table 200, and the supporting columns 122 and the hinged columns 121 play a main supporting role, so that the pressure and the abrasion to the connecting blocks are reduced.

In this embodiment or other embodiments, the two connecting blocks are a first face gear 410 and a second face gear 420, respectively, the first face gear 410 is coaxially fixed to the bottom of the rotating mechanism 210, and the second face gear 420 is connected to the driving mechanism 300 through a transmission mechanism 310. The first end face gear can realize 90-degree turnover along with the turnover table so as to realize separation and engagement with the second end face gear 420, and the first end face gear is convenient to be clutched and is convenient to be driven to rotate.

In this embodiment or other embodiments, the transmission mechanism 310 includes a transmission shaft 311 and a transmission gear set 312, the transmission shaft 311 rotates vertically to the rack 100, the second end face gear 420 is fixed to the top end of the transmission shaft 311, the driving mechanism 300 drives the transmission shaft 311 to rotate through the transmission gear set 312, and the transmission gear set 312 includes two bevel gears engaged with each other. The transmission mechanism 310 can vertically output the torque of the driving mechanism 300, so that the first end face gear 410 and the second end face gear 420 are meshed at a vertical angle, the driving mechanism 300 can be horizontally arranged, and the service life of the driving mechanism 300 is further prolonged.

In this embodiment or other embodiments, the engaging teeth 401 of the first end face gear 410 and the second end face gear 420 are both wedge-shaped, the tops of the engaging teeth 401 are both arranged in an inclined manner, and the arrangement of the wedge-shaped engaging teeth 401 and the tops in an inclined manner can play a guiding role in the engaging process after the first end face gear 410 is turned over, so that the first end face gear 410 and the second end face gear 420 can be further conveniently engaged.

In this embodiment or other embodiments, the meshing teeth 401 of the first face gear 410 are all concavely inclined towards the central axis, and the second face gears 420 are all convexly inclined towards the central axis; a slag discharge groove 402 is arranged between the meshing teeth 401. The first face gear 410 is formed in a groove shape with a concave middle, and is matched with a conical structure with a convex middle of the second face gear 420, meshing is easy to realize after rotation, and meshing reliability is high.

In this embodiment or other embodiments, at least two sets of gear rings 403 are respectively arranged on the first end face gear 410 and the second end face gear 420 in a one-to-one correspondence manner, the gear rings 403 are concentrically arranged, and the gear rings 403 are respectively composed of a plurality of meshing teeth 401. The meshing reliability is further improved, the number of the meshing teeth 401 is increased, the stress of the single meshing tooth 401 is dispersed, and the service life of the connecting block is prolonged.

In this or other embodiments, the driving mechanism 300 includes a speed reducer, and a braking device is disposed on the speed reducer. The speed reducer can keep the angle of the rotating shaft fixed under the action of the brake device, so that the temporary fixation of the second end face gear is ensured, and the damage of a connecting block caused by rotation in the process of turning and meshing is avoided.

According to the embodiment, the device not only can realize the vertical output of the torque of the driving mechanism and drive the rotating mechanism to rotate, but also can enable the rotating mechanism to be independently turned over so as to adapt to the requirements of different working conditions; the driving mechanism cannot be driven to synchronously act in the overturning process of the rotating mechanism, the load of the overturning lever is reduced, the driving mechanism can be ensured to be fixed in position, the service life of the driving mechanism is prolonged, and the maintenance frequency is reduced.

Although certain specific embodiments of the present invention have been described in detail by way of example, it should be understood by those skilled in the art that the foregoing examples are for purposes of illustration only and are not intended to limit the scope of the invention. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the invention. The scope of the invention is defined by the appended claims.

Claims (6)

1. A rotatable overturning structure comprises a rack, an overturning platform and a driving mechanism, wherein the driving mechanism is installed on the rack, and the rotatable overturning structure is characterized in that a hinged column and a supporting column are arranged at the top of the rack, one end of the bottom of the overturning platform is hinged to the hinged column, the other end of the overturning platform is erected on the supporting column, an overturning cylinder is hinged to the bottom of one end, close to the supporting column, of the overturning platform, the other end of the overturning cylinder is hinged to the rack, a rotating mechanism is connected to the overturning platform in a rotating mode, the driving mechanism and the rotating mechanism are connected through a connector, the connector comprises two connecting blocks which are matched with each other, the connecting blocks are respectively arranged on the overturning platform and the rack, and the connecting blocks can be connected and separated along with the rotation of the overturning platform; and a brake device is arranged on the driving mechanism.

2. The rotatable flipping structure of claim 1, wherein the two connecting blocks are a first end face gear and a second end face gear respectively, the first end face gear is coaxially fixed to the bottom of the rotating mechanism, and the second end face gear is connected to the driving mechanism through a transmission mechanism.

3. The rotatable flip structure of claim 2, wherein the transmission mechanism comprises a transmission shaft and a transmission gear set, the transmission shaft is vertically rotated to the frame, the second face gear is fixed to the top end of the transmission shaft, the driving mechanism drives the transmission shaft to rotate through the transmission gear set, and the transmission gear set comprises two bevel gears which are meshed with each other.

4. The rotatable flip structure of claim 2, wherein the meshing teeth of the first face gear and the second face gear are each wedge-shaped, and the tops of the meshing teeth are each arranged obliquely.

5. The rotatable flip structure of claim 4, wherein the meshing teeth of the first face gear are each concavely inclined toward the central axis, and the meshing teeth of the second face gear are each convexly inclined toward the central axis; and slag discharge grooves are formed between the meshing teeth.

6. The rotatable overturning structure according to claim 4 or 5, wherein the first face gear and the second face gear have at least two sets of gear rings in one-to-one correspondence, the gear rings are concentrically arranged, and the gear rings are respectively composed of a plurality of meshing teeth.

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