CN112623692A

CN112623692A - Material overturning mechanism

Info

Publication number: CN112623692A
Application number: CN202110139545.0A
Authority: CN
Inventors: 高国武
Original assignee: Dalian Field Manufacturing Co Ltd
Current assignee: Dalian Field Manufacturing Co Ltd
Priority date: 2021-02-02
Filing date: 2021-02-02
Publication date: 2021-04-09

Abstract

In the field of modern full-automatic steel pipe production lines, square pipe materials need to be placed according to a specific placing direction before entering a stacking link, when a stacking device needs to be completely placed down, a standing rectangular finished product needs to be turned into the placed down state through a material turning mechanism, the beat of continuous feeding work of the existing material turning mechanism and a feeding device is not consistent, the working process of the whole production line is influenced, and the generation efficiency is reduced. Therefore, the material turning action does not affect the beat of the whole production line, and the production efficiency is improved.

Description

Material overturning mechanism

Technical Field

The invention relates to the technical field of continuous material transportation in an automatic steel pipe production line, in particular to a material turning mechanism for continuously transporting and turning square materials.

Background

In the field of modern full-automatic steel pipe production lines, the most common continuous material products are round pipes and square pipes, in the link that the round pipes or the square pipes need to be bundled and stacked, the round pipes do not need to be turned in the material arrangement direction, but the square pipe materials need to be arranged according to a specific arrangement direction before entering the stacking link, because the square pipes are randomly arranged in the arrangement direction when being conveyed to a feeding device through a conveyor, the rectangular finished products are laid down on a conveyor belt of the feeding device in some cases and are erected on the conveyor belt in other cases, when the stacking device needs to be completely laid down, the erected rectangular finished products need to be turned to be laid down through a material turning mechanism, the existing material turning mechanism intercepts the rectangular finished products through a baffle plate, and then the erected rectangular finished products are pushed down through a pushing mechanism, however, in the process, the rectangular finished products must be stopped in the working area of the upender, which is not consistent with the beat of the continuous feeding work of the feeding device, and affects the working process of the whole production line to reduce the generation efficiency.

Disclosure of Invention

The embodiment of the invention provides a material turning mechanism which is provided with a material turning plate with a rotating shaft and an escapement notch, wherein a square material is embedded into the escapement notch by rotating the material turning plate around the rotating shaft, and then the square material is turned dynamically by following the rotation of the material turning plate, namely the square material is turned while being synchronously fed along with a continuous feeding driving belt, so that the material turning action does not influence the beat of the whole production line, and the production efficiency is improved.

On the one hand, the material turning mechanism comprises a material turning plate 1 arranged below a conveyor belt 2 used for conveying square materials f, and is characterized in that a rotating shaft 1a is arranged below the material turning plate 1, the material turning plate 1 is rotatably hinged below the conveyor belt 2 through the rotating shaft 1a and can do rotating motion around the rotating shaft 1a, an escapement notch 1b is further arranged above the material turning plate 1, and the escapement notch 1b can be embedded into the square materials f and can turn over the square materials f while moving along the conveying direction of the conveyor belt 2 through the rotating motion of the material turning plate 1 along the rotating shaft 1 a.

According to one aspect of the embodiment of the invention, a pushing baffle plate 2a is arranged on the conveyor belt 2, a pushing inclined surface 2at is arranged on one side, used for contacting the square material f, of the pushing baffle plate 2a, the shape of the pushing inclined surface 2at is that a certain distance is reserved between the lower side and the square material f when the upper end of the pushing inclined surface is contacted with the square material f, the pushing baffle plate 2a can push the square material f to move on the conveyor belt 2 along with the conveyor belt 2 and push the square material f to rotate along with the material turning plate 1 in the escape notch 1 b.

According to one aspect of the embodiment of the invention, the escapement notch 1b is provided with a blocking surface 1b1 and a top turning surface 1b2, the blocking surface 1b1 is used for abutting against the standing surface of the square material f, the top turning surface 1b2 is used for supporting the bottom surface of the square material f in contact with the conveyor belt 2, the blocking surface 1b1 and the top turning surface 1b2 are intersected with each other, and the top turning surface 1b2 can gradually jack up the square material f and separate from the conveyor belt 2 through the rotation of the material turning plate 1 along the rotating shaft 1 a.

According to one aspect of the embodiment of the invention, the resistance device z is further arranged, the resistance device z is provided with a telescopic cylinder z1, the extending end of the telescopic cylinder z1 is mutually connected with the material turning plate 1, and after the pushing baffle plate 2a pushes the square material f to be attached to the escapement notch 1b, the telescopic cylinder z1 applies a certain pushing force to the material turning plate 1 to enable the pushing baffle plate 2a and the escapement notch 1b to be mutually matched and hold the square material f to gradually turn along with the material turning plate 1.

According to an aspect of another embodiment of the invention, a resistance device z is further provided, the resistance device z is provided with a telescopic cylinder z1 and a thrust rod z2, the thrust rod z2 and the telescopic cylinder z1 are both hinged on a base d respectively, the extending end of the telescopic cylinder z1 is hinged in the middle of the thrust rod z2, the material turning plate 1 is further provided with a pulley 1c between the rotating shaft 1a and the escapement notch 1b, the thrust rod z2 is further provided with a sliding surface z2a towards one side of the pulley 1c, and the telescopic cylinder z1 pushes the thrust rod z2 to enable the sliding surface z2a and the pulley 1c to be in mutual contact and transmit a certain pushing force to the material turning plate 1 to enable the pushing baffle 2a and the escapement notch 1b to be matched with each other to hold the square material f to gradually turn along with the material turning plate 1.

According to an aspect of the embodiment of the present invention, the pushing baffles 2a are provided in plurality on the conveyor belt 2 and are evenly distributed around the circumference of the conveyor belt 2.

Drawings

Features, advantages and technical effects of exemplary embodiments of the present invention will be described below with reference to the accompanying drawings.

Description of the sequence numbers: the material turning plate comprises a material turning plate 1, a rotating shaft 1a, a escapement notch 1b, a pulley 1c, a blocking surface 1b1, a top turning surface 1b2, a conveyor belt 2, a pushing baffle plate 2a, a pushing inclined surface 2at, a resistance device z, a telescopic cylinder z1, a hinge shaft zj, a thrust rod z2, a sliding surface z2a, a base d and a square material f.

Fig. 1 is a schematic diagram of the basic structure layout of the first embodiment of the present invention.

Fig. 2 is a schematic diagram showing the material turning plate 1 according to the first embodiment of the present invention.

Fig. 3 is a schematic diagram of a square material f being picked up according to a first embodiment of the invention.

Fig. 4 is a schematic diagram of a square material f being turned upside down according to the first embodiment of the present invention.

Fig. 5 is a schematic diagram of the basic structure layout of the second embodiment of the present invention.

Fig. 6 is a schematic diagram showing the material turning plate 1 of the second embodiment of the present invention turned out.

Fig. 7 is a schematic view showing that a square material f is clamped according to a second embodiment of the present invention.

Fig. 8 is a schematic diagram of a second embodiment of the invention with a square material f turned upside down.

Fig. 9 is a layout diagram of the basic structure of the third embodiment of the present invention.

Fig. 10 is a schematic view showing the material turning plate 1 according to the third embodiment of the present invention turned out.

Fig. 11 is a schematic diagram showing a square material f being turned upside down according to a third embodiment of the present invention.

In the drawings, like parts are provided with like reference numerals. The figures are not drawn to scale.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following detailed description of the embodiments and the accompanying drawings are provided to illustrate the principles of the invention and are not intended to limit the scope of the invention, which is defined by the claims, i.e., the invention is not limited to the preferred embodiments described.

In the description of the embodiments of the present invention, it should be noted that "perpendicular" and "parallel" are not absolute meanings in a mathematical sense unless otherwise specified, and may be understood as "substantially perpendicular" and "substantially parallel".

According to the technical problem that square materials can be turned over while synchronously feeding along with a conveyor belt on the conveyor belt, the turning plate with the rotating shaft and the escapement notch is arranged, the square materials are embedded into the escapement notch through rotation of the turning plate around the rotating shaft, dynamic turning of the square materials is achieved through rotation of the square materials along with the turning plate, namely the square materials are turned over while synchronously feeding along with the continuously-fed conveyor belt, so that the turning action does not affect the rhythm of the whole production line, and the production efficiency is improved. The concrete structure of the square material conveying device comprises a material turning plate 1 arranged below a conveyor belt 2 used for conveying square materials f, a rotating shaft 1a is arranged below the material turning plate 1, the rotating shaft 1a is installed on a base d, the base d is arranged below the conveyor belt 2, and the material turning plate 1 is rotatably hinged below the conveyor belt 2 through the rotating shaft 1a and can rotate around the rotating shaft 1 a. An escapement notch 1b is arranged above the material turning plate 1, the escapement notch 1b can be embedded into a square material f, a blocking surface 1b1 and a top turning surface 1b2 which are mutually intersected are also arranged in the escapement gap 1b, the blocking surface 1b1 is used for abutting against the standing surface of the square material f, the top turning surface 1b2 is used for supporting the bottom surface of the square material f, which is contacted with the conveyor belt 2, the blocking surface 1b1 is matched with the top turning surface 1b2, by the rotation of the material-turning plate 1 along the revolving shaft 1a, the top-turning surface 1b2 will gradually lift the square material f up and out of the conveyor belt 2, the placing direction of the square materials f is gradually changed by the rotation of the material turning plate 1 to finally realize the turning of the square materials f, and the square materials f can synchronously move along the conveying direction of the conveying belt 2 while turning over through the displacement of the material turning plate 1 generated by the rotation in the same direction relative to the conveying belt 2. In addition, in order to realize the turning-out action of the material turning plate 1, a resistance device z is further arranged on the base d, the resistance device z is provided with a telescopic cylinder z1, the extending end of the telescopic cylinder z1 is provided with a hinged shaft zj, the hinged shaft zj is installed in the middle of the material turning plate 1, the mutual rotating connection between the extending end of the telescopic cylinder z1 and the material turning plate 1 is realized through the hinging of the hinged shaft zj, and the turning-out and the retraction of the material turning plate 1 can be realized through the telescopic motion of the telescopic cylinder z 1.

Referring to fig. 2, 3 and 4, the first embodiment of the present invention works specifically by, when square materials f needing to be turned over appear on the conveyor belt 2, the telescopic cylinder z1 starts to push the material turning plate 1 to turn over and turn out to be above the conveying plane of the conveyor belt 2 to intercept the square materials f to be turned over through the blocking surface 1b1, the telescopic cylinder z1 pulls the material turning plate 1 to turn over backwards after the square materials f needing to be turned over gradually follow the conveyor belt 2 to move and are embedded into the escape notch 1b, at the moment, the top turning surface 1b2 gradually jacks up the square materials f upwards and enables the square materials f to be separated from the conveyor belt 2 and turn over along with the turning of the top turning surface 1b2, and the blocking surface 1b1 bears the square materials f and gradually puts the square materials f which are turned over again onto the conveying plane of the conveyor belt 2 so as to achieve non-stop turning over of the square materials f.

According to the embodiments shown in fig. 5, 6, 7 and 8, the technical difference between the second embodiment and the first embodiment is that a blocking surface 1b1 is arranged above the material-stirring plate 1, and the blocking surface 1b1 is used for abutting against the standing surface of the square material f. Be equipped with on the conveyer belt 2 and promote baffle 2a, it is a plurality of on conveyer belt 2 to promote baffle 2a, and around the periphery evenly distributed of conveyer belt 2. A pushing inclined plane 2at is arranged on one side, used for contacting the square material f, of the pushing baffle plate 2a, the shape of the pushing inclined plane 2at is that a certain distance is reserved between the lower side and the square material f when the upper end of the pushing inclined plane 2a is in mutual contact with the square material f, the pushing baffle plate 2a can push the square material f to move on the conveyor belt 2 along the conveyor belt 2 and push the square material f to press on the blocking surface 1b1, the square material f can be gradually pressed to the gradually inclined blocking surface 1b1 by the rotation of the material turning plate 1 along the rotating shaft 1a, the placing direction of the square material f is gradually changed by the rotation of the material turning plate 1 gradually by the aid of the lower end of the pushing inclined plane 2at a certain distance from the square material f, and the square material f can be turned over finally by the same direction displacement of the conveyor belt 2 generated by the rotation of the material turning plate 1, and the square material f can be turned over at the same direction While following the conveying direction of the conveyor belt 2. The base d is further provided with a resistance device z, the resistance device z is provided with a telescopic cylinder z1, an extension end of the telescopic cylinder z1 is provided with a hinged shaft zj, the hinged shaft zj is installed in the middle of the material turning plate 1, the extension end of the telescopic cylinder z1 is rotatably connected with the material turning plate 1 through the hinged connection of the hinged shaft zj, and the telescopic cylinder z1 applies certain thrust to the material turning plate 1 to push the baffle plate 2a and the blocking surface 1b1 to be matched with each other and to hold the square material f to gradually turn along with the material turning plate 1.

According to another embodiment of the second embodiment of the invention, the material-overturning plate 1 may also be provided with a escapement notch 1b above, the escapement notch 1b can also be internally provided with a stop surface 1b1 and a top turning surface 1b2 which are mutually intersected, the blocking surface 1b1 is used for abutting against the standing surface of the square material f, the top turning surface 1b2 is used for supporting the bottom surface of the square material f, which is contacted with the conveyor belt 2, the blocking surface 1b1 is matched with the top turning surface 1b2, by the rotation of the material-turning plate 1 along the revolving shaft 1a, the top-turning surface 1b2 will gradually lift the square material f up and out of the conveyor belt 2, the placing direction of the square materials f is gradually changed by the rotation of the material turning plate 1 to finally realize the turning of the square materials f, and the square materials f can synchronously move along the conveying direction of the conveying belt 2 while turning over through the displacement of the material turning plate 1 generated by the rotation in the same direction relative to the conveying belt 2. Be equipped with on the conveyer belt 2 and promote baffle 2a, it is a plurality of on conveyer belt 2 to promote baffle 2a, and around the periphery evenly distributed of conveyer belt 2. The side that promotes baffle 2a is used for contacting square material f is equipped with and promotes inclined plane 2at, the shape that promotes inclined plane 2at leaves certain distance with square material f for its upper end when contacting each other with square material f below, promote baffle 2a can promote square material f follow conveyer belt 2 motion on conveyer belt 2 and promote square material f and press on stopping face 1b1 with cooperation square material f follows the upset of stirring board 1. The base d is further provided with a resistance device z, the resistance device z is provided with a telescopic cylinder z1, an extension end of the telescopic cylinder z1 is provided with a hinge shaft zj, the hinge shaft zj is installed in the middle of the material turning plate 1, the extension end of the telescopic cylinder z1 is rotatably connected with the material turning plate 1 through the hinge of the hinge shaft zj, and the telescopic cylinder z1 applies certain thrust to the material turning plate 1 to push the baffle plate 2a to be matched with the escapement notch 1b to hold the square material f to gradually turn along with the material turning plate 1.

According to the embodiments shown in fig. 9, 10 and 11, the technical features of the third embodiment of the present invention, which are different from the first embodiment, are that the resistance device z has a telescopic cylinder z1 and a thrust rod z2, the thrust rod z2 and the telescopic cylinder z1 are both hinged on a base d, the extending end of the telescopic cylinder z1 is hinged on the middle of the thrust rod z2, the material turning plate 1 is further provided with a pulley 1c between the rotation shaft 1a and the escapement notch 1b, the side of the thrust rod z2 facing the pulley 1c is further provided with a sliding surface z2a, and the telescopic cylinder z1 pushes the thrust rod z2 to make the sliding surface z2a contact with the pulley 1c and transmit a certain pushing force to the material turning plate 1 to realize the rotation of the material turning plate 1. The placing direction of the square materials f is gradually changed through the rotation of the material turning plate 1, and finally the square materials f are turned over, and the square materials f move synchronously along the conveying direction of the conveying belt 2 when turning over is achieved through the displacement, generated by the rotation of the material turning plate 1, in the same direction relative to the conveying belt 2.

According to another specific implementation manner of the third embodiment of the present invention, the conveyor belt 2 is provided with a plurality of pushing baffles 2a, and the pushing baffles 2a are provided on the conveyor belt 2 and are uniformly distributed around the periphery of the conveyor belt 2. The side that promotes baffle 2a is used for contacting square material f is equipped with and promotes inclined plane 2at, the shape that promotes inclined plane 2at leaves certain distance with square material f for its upper end when contacting each other with square material f below, promote baffle 2a can promote square material f follow conveyer belt 2 motion on conveyer belt 2 and promote square material f and press on stopping face 1b1 with cooperation square material f follows the upset of stirring board 1. The pushing baffle plate 2a and the escapement notch 1b are matched with each other to hold the square material f to gradually turn along with the material turning plate 1 by applying a certain thrust to the material turning plate 1 through the telescopic cylinder z 1.

It should be understood that the description herein of specific embodiments of the invention is exemplary and should not be construed as unduly limiting the scope of the invention. The scope of the invention is defined by the claims appended hereto, and encompasses all embodiments and obvious equivalents thereof that fall within their scope.

Claims

1. The utility model provides a stirring mechanism, is including setting up stirring board (1) in conveyer belt (2) below that is used for transporting square material (f), its characterized in that stirring board (1) below is equipped with a revolving axle (1 a), stirring board (1) through revolving axle (1 a) swivelling joint in conveyer belt (2) below and can be rotary motion around revolving axle (1 a), the top of stirring board (1) still is equipped with one and escaped notch (1 b), escaped notch (1 b) can imbed square material (f) and realize the upset when making square material (f) move along conveyer belt (2) direction of transfer through stirring board (1) along the rotary motion of revolving axle (1 a).

2. A mechanism according to claim 1, characterized in that the conveyor belt (2) is provided with a pushing baffle (2 a), one side of the pushing baffle (2 a) contacting the square material (f) is provided with a pushing inclined plane (2 at), the shape of the pushing inclined plane (2 at) is such that a certain distance is left between the lower side and the square material (f) when the upper side and the square material (f) contact each other, the pushing baffle (2 a) can push the square material (f) to follow the conveyor belt (2) on the conveyor belt (2) and push the square material (f) to follow the rotation of the material turning plate (1) along the rotation shaft (1 a) in the escapement gap (1 b).

3. A mechanism according to claim 2, characterized in that the escapement notch (1 b) is provided with a blocking surface (1 b 1) and a top-turned surface (1 b 2), the blocking surface (1 b 1) is used for abutting against the rising surface of the square material (f), the top-turned surface (1 b 2) is used for supporting the bottom surface of the square material (f) contacting the conveyor belt (2), the blocking surface (1 b 1) intersects the top-turned surface (1 b 2), and the top-turned surface (1 b 2) will gradually jack the square material (f) up and away from the conveyor belt (2) by the rotation of the material-turning plate (1) along the rotation axis (1 a).

4. The stirring mechanism according to claim 3, characterized in that a resistance device (z) is further arranged, the resistance device (z) is provided with a telescopic cylinder (z 1), the extending end of the telescopic cylinder (z 1) is connected with the stirring plate (1), and after the pushing baffle (2 a) pushes the square material (f) to be attached to the escapement notch (1 b), the telescopic cylinder (z 1) applies a certain pushing force to the stirring plate (1) to enable the pushing baffle (2 a) and the escapement notch (1 b) to be matched with each other to clamp the square material (f) to gradually overturn along with the stirring plate (1).

5. A upender mechanism according to claim 3, characterized in that a resistance device (z) is provided, which is provided with a telescopic cylinder (z 1) and a thrust rod (z 2), the thrust rod (z 2) and the telescopic cylinder (z 1) are respectively hinged on a base (d), the extending end of the telescopic cylinder (z 1) is hinged at the middle part of the thrust rod (z 2), the material turning plate (1) is also provided with a pulley (1 c) between the rotating shaft (1 a) and the escapement notch (1 b), one side of the thrust rod (z 2) facing the pulley (1 c) is further provided with a sliding surface (z 2 a), the telescopic cylinder (z 1) pushes the thrust rod (z 2) to enable the sliding surface (z 2 a) and the pulley (1 c) to be in mutual contact and transmit certain thrust to the material turning plate (1) to enable the pushing baffle (2 a) and the escapement notch (1 b) to be matched with each other to clamp the square material (f) and gradually turn along with the material turning plate (1).

6. A upender mechanism according to claim 4 or claim 5, characterized in that said push baffles (2 a) are provided in plurality on the conveyor belt (2) and are uniformly distributed around the periphery of the conveyor belt (2).