CN113104561B - Novel gas pipe processing material loading device - Google Patents

Abstract

The embodiment of the invention provides a novel gas pipe processing and feeding device, which comprises the following components: the pipe conveying device comprises a first conveying belt, a pipe and a second conveying belt, wherein the first conveying belt is used for receiving the pipe in the previous process, and the second conveying belt is used for conveying the pipe to the next process; further comprises: the pipe rolling device is connected with the first transmission belt and is used for receiving the pipe on the first transmission belt; the pipe rotating device is used for conveying the pipe on the pipe rolling device to the damping device; and the damping device is connected with the second conveyor belt and conveys the pipe of the damping device onto the second conveyor belt.

Description

Novel gas pipe processing material loading device

Technical Field

The invention relates to the technical field of gas coated steel pipe processing, in particular to a novel gas pipe processing and feeding device.

Background

The coated steel pipe is made of steel pipe as base pipe, plastic powder (such as epoxy resin) as coating material, plastic layer on its inner surface, and plastic layer or anticorrosive layer of other material on its outer surface. When different types of coated steel pipes are processed, corresponding plastic powder is selected according to different application conditions, and meanwhile, the requirements on an extruder and a die are different. The existing feeding device is used for feeding manually, and the required materials are placed on the feeding device manually and then fed, so that the working efficiency is greatly reduced.

Disclosure of Invention

The invention provides a novel gas pipe processing and feeding device, which aims to solve the problem that the existing feeding device is used for manually feeding, and required materials are manually placed on the feeding device and then fed, so that the working efficiency is greatly reduced. "problem. In order to achieve the above purpose, the present invention adopts the following technical scheme:

novel gas tubular product processing material loading device includes: the pipe conveying device comprises a first conveying belt, a pipe and a second conveying belt, wherein the first conveying belt is used for receiving the pipe in the previous process, and the second conveying belt is used for conveying the pipe to the next process; further comprises:

the pipe rolling device is connected with the first transmission belt and is used for receiving the pipe on the first transmission belt;

the pipe rotating device is used for conveying the pipe on the pipe rolling device to the damping device;

and the damping device is connected with the second conveyor belt and conveys the pipe of the damping device onto the second conveyor belt.

Further, the first conveyor belt is an inclined conveyor belt, and one side of the first conveyor belt, which is close to the pipe rolling device, is lower than the other side of the first conveyor belt; the second conveyor belt is a horizontal conveyor belt.

Further, the pipe rolling device includes: the device comprises a first supporting plate, a second supporting plate and a limiting block; the first supporting plate and the second supporting plate are fixedly arranged on the first conveyor belt; the first support plate is provided with a first slideway, the second support plate is provided with a second slideway, and the pipe slides on the first slideway and the second slideway; the limiting block prevents the pipe from sliding out of the first slide way and the second slide way.

Further, the first slide way and the second slide way are both obliquely arranged, and one side of the first slide way, which is close to the first conveyor belt, is lower than one side of the pipe rotating device.

Further, the pipe rotating device includes: the device comprises a straight cylinder, a plurality of connecting rods, a rotating shaft, two support columns, two bearings and a transmission assembly;

one end of each connecting rod is fixedly distributed on the outer wall of the straight cylinder in a circular array, the rotating shaft is coaxially arranged in the inner ring of the straight cylinder, the inner rings of the two bearings are coaxially arranged at two ends of the rotating shaft, and the outer rings of the two bearings are respectively arranged on the two support columns; the rotating shaft is driven to rotate through the transmission assembly.

Further, the transmission assembly comprises a driving wheel, a driven wheel, a belt, a motor and a mounting plate; the mounting plate is fixed on the support column, the motor is fixed on the mounting plate, the driving wheel is coaxially arranged at the shaft end of the motor, the driven wheel is coaxially arranged on the rotating shaft, and the driving wheel and the driven wheel are in matched transmission through a belt.

Further, also include buffer, buffer includes: a bump and a first spring; the other end of the connecting rod is provided with a deep hole, one end of the spring is fixed in the deep hole, the other end of the spring is fixedly connected to the protruding block, and the protruding block slides in the deep hole.

The damping device comprises a damping plate, a second spring and a bottom plate, wherein the damping plate is connected with the bottom plate through the second spring, and the bottom plate is fixedly arranged on the second conveyor belt; the damping plate conveys the pipe in the pipe rotating device to the second conveying belt.

Further, the top surface of the damping plate is an inclined surface, and one side of the damping plate, which is close to the pipe rotating device, is higher than one side of the second conveyor belt.

Compared with the prior art, the invention has the following advantages;

the invention provides a novel gas pipe processing and feeding device, which is provided with a pipe rolling device and is used for storing coated steel pipes on a first conveyor belt. And arranging a pipe rotating device to enable the coated steel pipe on the rolling device to rotate to the damping device. The damping device is arranged, so that the coated steel pipe better falls onto the second conveyor belt, and the damage of the coated steel pipe to the second conveyor belt is avoided. Through the arrangement, automatic feeding of the coated steel pipe is realized, the labor intensity of workers is reduced, and the feeding of the pipe is indirectly and orderly carried out.

In addition to the technical problems to be solved by the present invention, the technical features constituting the technical solutions and the advantages brought by the technical features of the technical solutions described above, other technical features included in the technical solutions and the advantages brought by the technical features that can be solved by the present invention are provided, and further detailed description will be made in the detailed description of the present invention.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

FIG. 1 is a front view of a novel gas pipe processing and feeding device provided by an embodiment of the invention;

FIG. 2 is a top view of a novel gas pipe processing and feeding device provided by an embodiment of the invention;

fig. 3 is a schematic diagram of the structure of B in fig. 1.

Reference numerals:

1. a first conveyor belt; 2. a pipe; 3. a pipe rolling device; 301. a first support plate; 302. a limiting block; 303. a second support plate; 304. a first slideway; 305. a second slideway; 4. a pipe rotating device; 401. a straight cylinder; 402. a connecting rod; 403. a rotating shaft; 404. a support column; 5. a damping device; 501. a shock absorbing plate; 502. a second spring; 6. a second conveyor belt; 7. a buffer device; 701. a bump; 702. a first spring; 8. a transmission assembly; 801. a mounting plate; 802. a motor; 803. a driving wheel; 804. a belt; 805. and (3) a driven wheel.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, the technical solutions in the embodiments of the present invention will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-3, an embodiment of the present invention provides a novel gas pipe 2 processing and feeding device, which includes: the pipe conveying device comprises a first conveying belt 1, a pipe 2 and a second conveying belt 6, wherein the first conveying belt 1 is used for receiving the pipe 2 in the previous process, and the second conveying belt 6 is used for conveying the pipe 2 to the next process; further comprises:

the pipe rolling device 3 is connected with the first transmission belt and used for receiving the pipe 2 on the first transmission belt 1;

the pipe rotating device 4 is used for conveying the pipe 2 on the pipe rolling device 3 to the damping device 5;

and the damping device 5 is connected with the second conveyor belt 6, and the pipe 2 of the damping device 5 is conveyed onto the second conveyor belt 6.

Specifically, as shown in fig. 1, the first conveyor belt 1 is an inclined conveyor belt, and one side of the first conveyor belt 1 close to the pipe rolling device 3 is lower than the other side; the second conveyor belt 6 is a horizontal conveyor belt.

Specifically, as shown in fig. 1 and 2, the pipe rolling device 3 includes: a first supporting plate 301, a second supporting plate 303 and a limiting block 302; the first support plate 301 and the second support plate 303 are fixedly arranged on the first conveyor belt 1; the first support plate 301 is provided with a first slideway 304, the second support plate 303 is provided with a second slideway 305, and the pipe 2 slides on the first slideway 304 and the second slideway 305; the stopper 302 prevents the pipe 2 from sliding out of the first slide 304 and the second slide 305.

The first slide 304 and the second slide 305 are both disposed obliquely, and a side of the first slide near the first conveyor 1 is slightly lower than a side of the pipe rotating device 4. In this way, the pipe 2 lifted by the first conveyor belt 1 slows down the speed of the pipe 2 by means of the inclined first slide way 304 and the second slide way 305, so that the impact collision to the limiting block 302 is lightened, and the phenomenon that the pipe 2 is in pits after collision is avoided.

It should be noted that, the first conveyor belt 1 and the second conveyor belt are both in the prior art; the inclined conveyor belt can select a conveyor belt with saw teeth on the surface, so that the pipe 2 is placed on a convenient conveyor belt, and the rolling of the pipe 2 is reduced; the first conveyor belt 1 and the second conveyor belt 6 are both fixed on the working surface by their own supporting legs, which can be fixed on the working surface by bolts. A first sliding may be provided on the top surface of the first support plate 301 in the same direction as the length of the first support plate 301; a second slide may be provided on the top surface of the second support plate 303 in the same direction as the length of the second support plate 303. As shown in fig. 1 and 2, the left ends of the first support plate 301 and the second support plate 303 may be welded on top of the support legs of the first conveyor belt 1, so that the pipe 2 falls from the first conveyor belt 1 onto the first slideway 304 and the second slideway. As shown in fig. 1 and 2, in order to prevent the relative displacement between the pipe rolling device 3 and the pipe rotating device 4 and ensure that the pipe 2 slides smoothly in the pipe rolling device 3, a connecting piece or a connecting plate may be used to fixedly connect the other end of the first supporting plate 301 and the other end of the second supporting plate 303 with the two supporting columns 404 respectively, which may be welded or bolted.

Specifically, the pipe rotating apparatus 4 includes: the device comprises a straight cylinder 401, a plurality of connecting rods 402, a rotating shaft 403, two support columns 404, two bearings and a transmission assembly 8;

one end of each connecting rod 402 is fixedly distributed on the outer wall of the straight cylinder 401 in a circular array, the rotating shaft 403 is coaxially arranged in the inner ring of the straight cylinder 401, the inner rings of the two bearings are coaxially arranged at two ends of the rotating shaft 403, and the outer rings of the two bearings are respectively arranged on the two support columns 404; the rotation shaft 403 is driven to rotate by the transmission assembly 8.

The transmission assembly 8 comprises a driving wheel 803, a driven wheel 805, a belt 804, a motor 802 and a mounting plate 801; the mounting plate 801 is fixed on the support column 404, the motor 802 is fixed on the mounting plate 801, the driving wheel 803 is coaxially arranged at the shaft end of the motor 802, the driven wheel 805 is coaxially arranged on the rotating shaft 403, and the driving wheel 803 and the driven wheel 805 are cooperatively driven through a belt 804.

Also included is a cushioning device 7, the cushioning device 7 comprising: a bump 701 and a first spring 702; a deep hole is formed in the other end of the connecting rod 402, one end of the spring is fixed in the deep hole, the other end of the spring is fixedly connected to the protruding block 701, and the protruding block 701 slides in the deep hole. The buffer device 7 is provided to prevent the pipe 2 from directly sliding out of the connecting rod 402 by centrifugal force when the pipe 2 is rotated to the side close to the damper 5.

It should be noted that, the connection between the connecting rod 402 and the straight cylinder 401 may be a bolt connection, so that the connecting rod 402 is convenient to replace after being damaged; the number of the whole bodies formed by the connecting rods 402 and the straight cylinders 401 can be two, as shown in fig. 2, the connecting rods 402 are located between the first supporting plate 301 and the second supporting plate 303, and when the pipe rolling device 3 rotates, the pipe 2 in the pipe rolling device 3 is conveniently conveyed to the damping device 5. The outer ring of the bearing can be welded on the top of the support column 404, and a through hole can be formed in the support column 404, and the outer ring of the bearing is coaxially arranged in the through hole. The bottom of the support column 404 is welded with an ear plate and bolts are used to secure the support column 404 to the work surface. The motor 802 is a single-rotation motor 802, and when the pipe rotating device 4 rotates clockwise, the buffer device 7 is arranged as shown in fig. 1; in order to prevent the pipe 2 from falling off, a buffer device 7 can be further arranged on the opposite surface of the support column 404 provided with the buffer device 7, so that the pipe rotating device 4 is prevented from falling off when clamping the pipe 2.

Specifically, the damping device 5 comprises a damping plate 501, a second spring 502 and a bottom plate, wherein the damping plate 501 is connected with the bottom plate through the second spring 502, and the bottom plate is fixedly arranged on the second conveyor belt 6; the damper plate 501 conveys the tube 2 in the tube turning device 4 onto the second conveyor belt 6.

The top surface of the damper plate 501 is an inclined surface, and the side thereof close to the pipe rotating apparatus 4 is higher than the side of the second conveyor belt 6. The tube 2 is conveniently slid onto the second conveyor belt 6.

It should be noted that, as shown in fig. 1, the bottom end of the second spring 502 is welded on the top surface of the bottom plate, the second conveyor belt 6 is fixedly disposed on the bottom plate, so that the right end of the damper plate 501 is just contacted with the left end of the second conveyor belt 6, the damper plate 501 may be disposed as shown in fig. 2, the left end of the damper plate 501 is located between the pipe rotating devices 4, and when the pipe 2 is rotated to the damper plate 501 by the pipe rotating devices 4, the damper plate 501 pads the pipe 2 in the pipe rotating devices 4 off the connecting rod 402 and the buffer device 7, and slides the pipe 2 onto the second conveyor belt 6 by means of the damper plate 501. In order to prevent the pipe rotating device 4 and the buffer device 7 from moving, the bottom plate is fixedly connected with the support column 404 through a connecting piece or a connecting plate, and the fixed connection is welded or bolted.

The pipe rotating device transfers the pipes staying on the pipe rolling device to the damping device indirectly and orderly, so that stable pipe transmission is realized, and the accumulation of the pipes on the second conveying belt is avoided.

Working principle:

the pipe 2 is transmitted to the pipe rolling device 3 from the left end of the first conveyor belt 1 with saw teeth, two ends of the pipe 2 are respectively positioned on the first slideway 304 and the second slideway until being blocked by the limiting block 302, the pipe rotating device 4 rotates clockwise, the pipe 2 stopped on the pipe rolling device 3 is pulled up and then rotates, the pipe 2 is blocked by the buffer device 7, the pipe 2 is stopped on the connecting rod 402 for a short time, when the pipe 2 is rotated to be in contact with the buffer plate 501, the buffer plate 501 pads the pipe 2 on the connecting rod 402, the pipe 2 is separated from the connecting rod 402 and the buffer device 7, the pipe 2 slides onto the second conveyor along the inclined buffer plate 501, and the pipe 2 is conveyed to the next procedure by the second conveyor.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims (8)

1. Novel gas tubular product processing material loading device includes: the pipe conveying device comprises a first conveying belt, a pipe and a second conveying belt, wherein the first conveying belt is used for receiving the pipe in the previous process, and the second conveying belt is used for conveying the pipe to the next process; characterized by further comprising:

the pipe rolling device is connected with the first conveyor belt and is used for receiving the pipe on the first conveyor belt;

the pipe rotating device is used for conveying the pipe on the pipe rolling device to the damping device; wherein, tubular product rotating device includes: the device comprises a plurality of connecting rods and straight cylinders, wherein one ends of the connecting rods are fixedly distributed on the outer wall of the straight cylinders in a circular array, the number of the straight cylinders is two, the connecting rods with the same number are connected to the two straight cylinders, and the positions of the connecting rods on the two straight cylinders are in one-to-one correspondence and are used for conveying the pipe to the damping device in a rotating mode;

the damping device is connected with the second conveyor belt and conveys the pipe of the damping device to the second conveyor belt; wherein, damping device includes: the shock absorption plate is provided with a protruding part at one side close to the pipe rotating device, wherein the width of the protruding part is smaller than the distance between the two corresponding connecting rods and is used for cushioning the pipe rotating to the shock absorption plate, and the right end of the shock absorption plate is connected with the left end of the second conveyor belt;

a cushioning device, the cushioning device comprising: a bump and a first spring; a deep hole is formed in the other end of the connecting rod, one end of the spring is fixed in the deep hole, the other end of the spring is fixedly connected to the protruding block, and the protruding block slides in the deep hole; when the connecting rod rotates to the upper part of the damping device, the damping device is arranged on the upper end face of the connecting rod.

2. The novel gas pipe processing and feeding device according to claim 1, wherein the first conveyor belt is an inclined conveyor belt, and one side of the first conveyor belt, which is close to the pipe rolling device, is lower than the other side of the first conveyor belt; the second conveyor belt is a horizontal conveyor belt.

3. The novel gas pipe processing and feeding device according to claim 1, wherein the pipe rolling device comprises: the device comprises a first supporting plate, a second supporting plate and a limiting block; the first supporting plate and the second supporting plate are fixedly arranged on the first conveyor belt; the first support plate is provided with a first slideway, the second support plate is provided with a second slideway, and the pipe slides on the first slideway and the second slideway; the limiting block prevents the pipe from sliding out of the first slide way and the second slide way.

4. The novel gas pipe processing and feeding device according to claim 3, wherein the first slide rail and the second slide rail are obliquely arranged, and one side of the first slide rail, which is close to the first conveyor belt, is lower than one side of the pipe rotating device.

5. The novel gas pipe machining and feeding device according to claim 1, wherein the pipe rotating device further comprises: the device comprises a rotating shaft, two support columns, two bearings and a transmission assembly;

the rotating shaft is coaxially arranged in the inner ring of the straight cylinder, the inner rings of the two bearings are coaxially arranged at two ends of the rotating shaft, and the outer rings of the two bearings are respectively arranged on the two support columns; the rotating shaft is driven to rotate through the transmission assembly.

6. The novel gas pipe processing and feeding device according to claim 5, wherein the transmission assembly comprises a driving wheel, a driven wheel, a belt, a motor and a mounting plate; the mounting plate is fixed on the support column, the motor is fixed on the mounting plate, the driving wheel is coaxially arranged at the shaft end of the motor, the driven wheel is coaxially arranged on the rotating shaft, and the driving wheel and the driven wheel are in matched transmission through a belt.

7. The novel gas pipe processing and feeding device according to claim 1, wherein the damping device further comprises a second spring and a bottom plate, the damping plate is connected with the bottom plate through the second spring, and the bottom plate is fixedly arranged on the second conveyor belt; the damping plate conveys the pipe in the pipe rotating device to the second conveying belt.

8. The novel gas pipe processing and feeding device according to claim 7, wherein the top surface of the damping plate is an inclined surface, and one side of the damping plate, which is close to the pipe rotating device, is higher than one side of the second conveyor belt.

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