CN220635110U - Powder pouring groove for large-pipe-diameter plastic-coated steel pipe - Google Patents

Abstract

The utility model discloses a large-pipe-diameter plastic-coated steel pipe powder pouring groove, which comprises a groove body, a supporting plate, a reinforcing shaft, a partition plate, a connecting shaft and a flattening device, wherein the supporting plate is arranged on the groove body; the groove body is integrally arranged in a trapezoid shape, the inside of the groove body comprises two parts, namely a trapezoid groove at the top and an arc groove at the bottom, and the trapezoid groove and the arc groove are integrally arranged; a supporting plate is arranged at the bottom of the groove body, a semicircular reinforcing shaft is arranged at the bottom of the supporting plate, one end of the reinforcing shaft is connected with a cylindrical connecting shaft, a partition plate with the cross section shape matched with that of the groove body and the supporting plate is arranged between the connecting shaft and the groove body, and a flattening device is arranged on a notch at the top of the groove body in a sliding connection manner; the powder pouring groove is simple in structure, has strong bending resistance, can automatically feed two materials and quantitatively feed the materials together with the powder adding device, improves the working efficiency and reduces the cost.

Description

Powder pouring groove for large-pipe-diameter plastic-coated steel pipe

Technical Field

The utility model relates to the technical field of plastic coating equipment, in particular to a large-diameter plastic coated steel pipe powder pouring groove.

Background

The plastic-coated steel pipe, also called plastic-coated pipe, steel-plastic composite pipe and plastic-coated composite steel pipe, is characterized by that it uses steel pipe as base body, and adopts the processes of spraying, rolling, soaking and sucking to weld a layer of plastic anticorrosive layer on the inner surface of steel pipe (bottom pipe) or weld the steel-plastic composite steel pipe with plastic anticorrosive layer on its inner surface and outer surface. The anti-corrosion coating has the characteristics of protruding anti-corrosion performance, high compressive strength, long service life, smooth inner surface, good liquid flow performance and the like, so that the anti-corrosion coating is rapidly accepted by the market and is widely used. In the process of producing the plastic-coated steel pipe, a material layer needs to be sprayed on the inner wall, in the process of actual production, in the process of adopting the uniform rolling coating of powder melting, the powder needs to be uniformly poured into the pipeline, and then, the powder is uniformly rolled on the inner wall of the pipeline after hot melting. The quantitative powder is firstly put into a container and then is sent into the pipeline, and the pipeline rolls and simultaneously slowly discharges, so that the powder is rolled on the surface of the pipeline after being melted in the rolling process. In the actual production process, the following problems occur in the existing operation by manually pouring the split material into one tank and then feeding the tank together with the powder into the pipe and then pouring the powder: 1. the powder pouring is performed manually, so that the working efficiency is very low, and the powder pouring is inconvenient to quantify; 2. when powder is needed to be conveniently quantified, the powder tank is fixed, and because the powder can be quantified only through the volume of the tank when manually poured, the tank can be replaced by rolling coating aiming at the requirements of different pipe diameters or the degree of the rolling coating, the operation is complex, and the working efficiency is too low; 3. in the actual production process, the position of the powder tank is fixed and cannot be adjusted, so that the quality of the soil is reduced due to different positions of the powder tank for the rolling coating of different pipe diameters, even if the rolling coating of the powder tank is thin at one thick position of the rolling coating surface at an unsuitable position, the quality accident of the rolling coating failure is generated seriously, manual calibration is needed for each rolling coating, and the working efficiency is seriously influenced; fourth, in the whole operation process, the powder poured into the pipeline is uneven, so that the surface of the roll coating is uneven.

Disclosure of Invention

The utility model aims to overcome the defects that in the prior art, when powder is needed to be conveniently quantified, a powder tank is fixed, and because the powder tank can only be quantified through the volume of the tank when the powder is manually poured, the tank can be replaced by rolling coating according to the requirements of different pipe diameters or the degree of rolling coating, the operation is complex and the working efficiency is too low, and provides a full-automatic large-pipe-diameter plastic coated steel pipe inner surface thermoplastic device.

The utility model aims to realize a large-pipe-diameter plastic-coated steel pipe powder pouring groove by the following technical scheme, which comprises a groove body, a supporting plate, a reinforcing shaft, a partition plate, a connecting shaft and a flattening device; the groove body is integrally arranged in a trapezoid shape, the inside of the groove body comprises two parts, namely a trapezoid groove at the top and an arc groove at the bottom, and the trapezoid groove and the arc groove are integrally arranged; the bottom of the groove body is provided with a supporting plate, the bottom of the supporting plate is provided with a semicircular reinforcing shaft, one end of the reinforcing shaft is connected with a cylindrical connecting shaft, a partition plate with a matched cross-section shape is arranged between the connecting shaft and the groove body and the supporting plate, and a flattening device is arranged on a notch at the top of the groove body in a sliding connection mode.

Preferably, the supporting plate is bent into a wavy shape, a hole is formed in the bent part of the plate, one end of the supporting plate is fixedly connected with the partition plate, the top of the supporting plate is fixedly connected with the groove body at the hole, a connecting plate is fixedly connected to the side face of the supporting plate, and the connecting plate is fixedly connected with the reinforcing shaft.

Preferably, a through hole is formed in the bottom of the partition board, and the reinforcing shaft is inserted into the through hole.

Preferably, the flattening device comprises a flattening inner plate, an outer clamping plate, a connecting clamping shaft, a clamping groove and a pin hole; the flattening inner plate is a trapezoid plate which is firstly matched with the trapezoid groove in the groove body and comprises an inner part of the groove body and an outer part exceeding the groove body; an outer clamping plate is connected and arranged on the outer side of the flattening inner plate, and a chute formed by the outer clamping plate and the flattening inner plate is slidingly connected on the chute edge of the chute body; the top of the flattening inner plate is connected with a connecting clamping shaft, a clamping groove is formed in the connecting clamping shaft, and a pin hole is formed in the clamping groove.

Preferably, the inner portion of the flattening inner plate is disposed obliquely.

Preferably, a scale is provided on the inner side surface of the tank body.

The utility model has one of the following advantages:

1. in this device, after the pipeline enters into pipeline rotating device, the pipeline is rotated by pipeline rotating device drive, simultaneously, heating device preheats or heats the pipeline, in this time quantum, add powder device to the powder amount of setting of pouring into the powder inslot, then, the powder pouring device is with the powder feeding into the pipeline inboard, after reaching the temperature of setting or time, the powder pouring device drive pouring into the powder groove and topple over, the powder that falls into the pipeline inwards, then along with the roll of heating and pipeline, the powder that falls melts the plastic-coated on the pipeline inner wall. The whole process is controlled uniformly by the controller, so that the working efficiency is higher, the control is more accurate, and meanwhile, the manual labor force is saved;

2. the powder pouring groove has a simple structure, has strong bending resistance, can automatically count two times and amount together with the powder adding device, improves the working efficiency and reduces the cost input;

3. in the process of adding materials, the device can control the running speed of the bin by the controller, realize automatic feeding and simultaneously can quantify, and can well replace manual material adding by assisting with the quantification of the flattening device, thereby improving the efficacy and simultaneously quantifying;

4. the device has the advantages of more convenient overall control, smoother use, higher working efficiency and capability of controlling the overall quality;

5. the device can enable the powder pouring device to realize adjustment in three directions in a coordinate system, so that when the whole device is suitable for different pipelines, the whole device is only required to be arranged at a corresponding position in the controller in advance according to specific requirements and fixed into a certain parameter mode, automatic adjustment can be realized only by mode selection according to specific pipelines in the use process, and automatic adjustment, material adding and feeding can be realized by combining the powder adding device and the powder pouring groove. The investment of manual labor is reduced, the efficacy is improved, and the quality is ensured.

Drawings

Fig. 1 is a schematic structural view of the present thermoplastic apparatus.

Fig. 2 is a schematic structural view of the powder pouring tank.

Fig. 3 is a side view of the pouring spout.

Fig. 4 is a schematic diagram of a flattening apparatus.

Fig. 5 is a schematic view of a separator structure.

Fig. 6 is a schematic structural diagram of the powder adding device.

Fig. 7 is a side view of the powder adding device.

Fig. 8 is a schematic structural view of the powder pouring device.

Fig. 9 is a side view of the powder adding device.

Fig. 10 is a top view of the height adjustment mechanism.

In the figure, a powder pouring groove (1), a groove body (11), a supporting plate (12), a reinforcing shaft (13), a partition plate (14), a connecting shaft (15), a flattening device (16), a flattening inner plate (161), an outer clamping plate (162), a connecting clamping shaft (163), a clamping groove (164) and a pin hole (165); the powder adding device comprises a powder adding device (2), a first guide rail (21), a suspension shaft (22), a first guide rail rack (23), a first guide rail gear (24), a first guide rail gear rotating shaft (25), a first driving gear (26), a second driving gear (27), a powder adding motor (28), a storage bin (29), a discharge hole (210) and a material pipe (211); the powder pouring device comprises a powder pouring device (3), a second guide roller (31), a second guide rail gear (32), a first movable platen (33), a second movable platen (34), a slide column (35), a third movable platen (36), a bearing seat (37), a powder pouring motor (38), a telescopic device (39), a second movable platen motor (310), a first movable platen motor (311), a third driving gear (312) and a fourth driving gear (313).

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

In addition, the embodiments of the present utility model and the features of the embodiments may be combined with each other without collision.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present utility model, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships conventionally put in use of the inventive product, or are directions or positional relationships conventionally understood by those skilled in the art, are merely for convenience of describing the present utility model and for simplifying the description, and are not to indicate or imply that the apparatus or element to be referred to must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The full-automatic large-diameter plastic coated steel pipe inner surface thermoplastic device shown in fig. 1 comprises a pipeline rotating device and a heating device, wherein the pipeline rotation is used for driving the pipeline to rotate, a roller driven by a motor is usually used for driving the pipeline to rotate, and the heating device is a device for heating the pipeline in the process of rolling the pipeline, and is usually an electric heating device. The device carries out automatic processing to the roll plastic-coated of powder material under the basis that these two devices exist, mainly go on the powder material in the pipeline process of material loading is automatic, specifically, this device sets up the device of falling powder 3 and is used for carrying out automatic feeding to the powder in one side of pipeline rotating device, set up on the device of falling powder 3 and fall powder groove 1 and be used for holding the powder, hang the top that the device of falling powder groove 1 is close to pipeline rotating device one end and set up and add powder device 2 and be used for adding the material to falling powder inslot 1, pipeline rotating device, heating device, add powder device 2, fall powder device 3 and be connected to same controller. So, in this device, after the pipeline enters into pipeline rotating device, the pipeline is rotated by pipeline rotating device drive, simultaneously, heating device preheats or heats the pipeline, in this time quantum, add powder device 2 to the powder amount of setting of adding in the powder pouring groove 1, then, powder pouring device 3 sends the powder to the pipeline inboard, when reaching the temperature of setting or time back, powder pouring device 3 drive powder pouring groove 1 emptys, pour the powder to the pipeline inwards, after the powder falls into the pipeline, then along with heating and the roll of pipeline, the powder that falls melts the plastic-coated on the pipeline inner wall. The whole process is controlled uniformly through the controller, so that the working efficiency is higher, the control is more accurate, and meanwhile, the manual labor force is saved.

In another embodiment, since the powder tank must be fixed when the powder is needed to be conveniently dosed, the powder tank can be replaced only by the volume of the tank when the powder is manually poured, the operation is complicated and the working efficiency is too low for the roll coating with different pipe diameters or the requirements of the roll coating back degree. The application provides a large-pipe-diameter plastic-coated steel pipe powder pouring groove, namely a powder pouring groove 1, as shown in figures 2 to 5, which comprises a groove body 11, a supporting plate 12, a reinforcing shaft 13, a partition plate 14, a connecting shaft 15 and a flattening device 16. In this device, the cell body 11 wholly sets up to trapezoidal, and its inside includes two parts, is trapezoidal groove at top and the arc wall of bottom respectively, with the two integration setting, can possess like this and certain to supporting strength, and its capacity also can be guaranteed. Because the pipeline has a certain length, when the pipeline is penetrated into the pipeline, the whole powder pouring groove 1 is provided with a cantilever beam, so that in order to improve the pointed strength of the groove body 11, the bending is avoided, the strength of the groove body is improved, the bottom of the groove body 11 is provided with the supporting plate 12, and the bottom of the supporting plate 12 is provided with the semicircular reinforcing shaft 13. In order to facilitate the rotation of the driving groove 11 for pouring, a cylindrical connecting shaft 15 is connected and arranged at one end of the reinforcing shaft 13, and the connecting shaft 15 is directly connected to a driving device of the powder pouring device 3. In order to ensure that the whole powder pouring groove 1 has better integrity and is convenient to connect and fasten, a partition plate 14 with the cross section shape matched with that of the groove body 11 and the supporting plate 12 is arranged between the connecting shaft 15 and the groove body, and a flattening device 16 is arranged on the notch at the top of the groove body 11 in a sliding connection manner for facilitating quantification.

In this device, in order to improve the supporting strength, avoid buckling, this device sets up fagging 12 as a board and buckles into the wave form, is provided with the hole in the department of buckling of board, so, the in-process of making, just accessible welded connected mode is in the hole, and the department welds fastening connection as an organic whole. One end of the supporting plate 12 is fixedly connected with the partition plate 14 to form a step convenient to position, the top of the supporting plate 12 is fixedly connected with the groove body 11 at the hole, the side surface of the supporting plate is fixedly connected with a connecting plate 17, and the connecting plate 17 is fixedly welded with the reinforcing shaft 13. In addition, the bottom of the partition 14 is provided with a through hole, and the reinforcing shaft 13 is inserted into the through hole to improve the support.

In another embodiment, the flattening device is used for flattening the powder in the tank 11, and the flattening device 16 includes a flattening inner plate 161, an outer clamping plate 162, a connecting clamping shaft 163, a clamping groove 164 and a pin hole 165. Specifically, the flattening inner plate 161 is provided as a trapezoidal plate that is fitted to the trapezoidal groove in the tank body 11, including at the inner portion of the tank body 11 and the outer portion beyond the tank body 11. The inner portion thereof is adjusted in length according to specific capacity requirements, and when the capacity in the tank 11 is required to be large, the depth of the flattening inner plate 161 is reduced, so that the amount of being blocked off during flattening is small, and vice versa. In order to facilitate spreading at the top, an outer clamping plate 162 is connected to the outer side of the flattening inner plate 161, and the outer clamping plate 162 and a chute formed by the flattening inner plate 161 are slidingly connected to the chute edge of the chute body 11. The flattening device 16 has been used for flattening a quantitative material by manual driving, but is obviously insufficient in the work advocating efficiency, therefore, the device is provided with the connecting clamping shaft 163 at the top of the flattening inner plate 161, the connecting clamping shaft 163 is provided with the clamping groove 164, the clamping groove 164 is provided with the pin hole 165, the connecting clamping shaft 163 is connected to one side of the material pipe 211 of the powder adding device 2 through a telescopic shaft, and thus, the material is added into the material tank under the powder device 2, and the material is subjected to the material flattening quantitative. Therefore, the powder adding device 2 is assisted by the flattening device 16 to actively and quantitatively add materials, the manpower input is reduced, and the automatic control can be realized to improve the working efficiency.

In another embodiment, the inner portion of the flattening inner plate 161 is inclined for convenient and quick spreading. Meanwhile, a scale is arranged on the inner side surface of the groove body 11 so as to facilitate the operator to check again.

The powder pouring groove is simple in structure, has strong bending resistance, can automatically feed out two materials and amount with the powder adding device 2, improves the working efficiency and reduces the cost.

In another embodiment, the powder pouring is performed manually, the working efficiency is very low, and the powder pouring is inconvenient to quantify, so as to assist the powder pouring groove 1 to realize automatic powder adding and quantifying together, and the embodiment provides a powder adding device for the inner surface of a large-diameter plastic coated steel tube, namely a powder adding device 2, shown in fig. 6 to 7, which comprises a first guide rail 21, a suspension shaft 22, a storage bin 29, a discharge hole 210 and a material pipe 211. In this device, first guide rail 21 hangs the top of establishing at pouring powder groove 1 through hanging solid axle 22, and the slip joint sets up feed bin 29 on first guide rail 21, sets up discharge gate 210 in the bottom of feed bin 29, and discharge gate 210 connects and sets up material pipe 211, and material pipe 211 stretches to pouring powder groove 1 top. In this way, while the first guide rail 21 is slid by driving the bin 29, the material is uniformly added into the powder pouring tank 1 through the material pipe 211 while being flattened by the flattening device 16. In order to avoid blocking, the discharge hole is arranged in an hourglass shape, the electromagnetic valves are arranged on the material pipe 211 and connected to the controller, and the electromagnetic valves are arranged in two, at the bottom of the discharge hole 210 and the bottom of the material pipe 211 respectively, so that the running speed of the material bin 29 can be controlled by the controller to realize automatic feeding and simultaneously to be quantitative in the process of adding materials, the flattening device 16 is assisted to be quantitative, the manual material adding can be well replaced, the efficiency is improved, and meanwhile, the quantitative can be carried out.

In another embodiment, the first rail 21 is provided as a rack and pinion rail for ease of movement. Specifically, the first guide rail 21 is L-shaped, a first guide rail rack 23 is arranged in the first guide rail 21, a rotating shaft 25 is arranged at the bottom of the storage bin 29 in a switching manner, one end of the rotating shaft 25 is connected with a first guide rail gear 24, and the first guide rail gear 24 is meshed with the first guide rail rack 3; a first driving gear 26 is fixedly arranged on the rotating shaft 25, a powder adding motor 28 is arranged on one side of the bottom of a storage bin 29, a second driving gear 27 is fixedly arranged on the output rotating shaft of the powder adding motor 28, and the second driving gear 27 is in meshed connection with the first driving gear 26. In this way, the whole powder adding device 2 is driven by the powder adding motor 28 to move on the first guide rail 21 to add materials.

In order to stably move the stock bin 29, the stock bin 29 is arranged in a trolley shape, and the first guide rack 23 is symmetrically arranged in two groups of four. Meanwhile, the powder adding motor 28 is configured as a double output shaft motor, or is enabled to output two rotation positions simultaneously through other gearboxes and the like, and then is connected with the left and right first rail gears 24 respectively.

In order to make the overall arrangement more reasonable, the discharge port 210 is arranged at a side far away from the second driving gear 27, and the bottom inside the storage bin 29 is obliquely arranged towards the discharge port 210.

In another embodiment, in the actual production process, the powder tank can only move forwards and backwards, the powder tank cannot be adjusted, the quality of the soil can be reduced due to different positions of the powder tank when the powder tank is used for rolling coating of different pipe diameters, even the rolling coating at an unsuitable position can lead to a quality accident that the rolling coating surface is thick and thin, and the rolling coating is invalid in serious cases, manual calibration is needed for each rolling coating, and the working efficiency is seriously affected. For this purpose, the device provides an automatic powder feeding device, namely a powder pouring device 3, for the inner surface of a large-diameter plastic coated steel pipe shown in fig. 8 to 10, and the automatic powder feeding device comprises a second guide roller 31, a first movable platen 33, a second movable platen 34, a third movable platen 36, a powder pouring motor 38 and a height adjusting mechanism. A second guide roller 31 is arranged on the ground, a first movable platen 33 is arranged on the second guide roller 31, a second movable platen 34 is arranged on the first movable platen 33 in a sliding manner, a height adjusting mechanism is arranged on the second movable platen 34, and a third movable platen 36 is arranged at the top of the height adjusting mechanism; a bearing seat 37 is arranged on the third movable platen 36, and a powder pouring motor 38 is arranged on one side of the bearing seat 37; the powder pouring groove 1 is connected to the bearing seat 37 in a switching way and is connected with the output shaft of the powder pouring motor 38. So just so make the powder pouring device 3 can realize the adjustment of three orientation in the coordinate system for whole equipment is when adapting to different pipelines, only needs to set up corresponding position and fix into a certain parameter mode according to specific needs in the controller in advance, only need carry out mode selection according to specific pipeline in the use, just can realize automatic adjustment, adds material and material loading in combination powder adding device 2 and powder pouring groove 1. The investment of manual labor is reduced, the efficacy is improved, and the quality is ensured.

In another embodiment, in order to facilitate the running of the powder pouring device 3, the powder pouring groove 1 is extended into the pipeline, and the second guide roller 31 is arranged as a rack-and-pinion guide rail. Specifically, the racks of the second guide roller 31 are engaged with and connected with second guide rail gears 32, the second guide rail gears 32 are symmetrically arranged in two groups through a rotating shaft, and the rotating shaft is fixedly provided with a first movable bedplate 33 through a connecting frame; a first movable platen motor 311 is provided at the bottom of the first movable platen 33, a fourth driving gear 313 is fixedly provided on a conveying shaft of the first movable platen motor 311, the fourth driving gear 313 is engaged with a third driving gear 312, and the third driving gear 312 is fixedly provided on a rotating shaft of the second rail gear 32.

To facilitate positioning, driving and adjustment, the first moving platen motor 311 is configured as a dual output shaft motor. Meanwhile, a screw is arranged on the second movable platen 34 in a switching way, one end of the screw is connected to an output shaft of the second movable platen motor 310, and the second movable platen motor 310 is arranged at one end of the first movable platen 33.

In another embodiment, because the powder pouring tank 1 is a cantilever beam, in order to improve the stability of the whole third movable platen 36, the height adjusting mechanism comprises four slide posts 35 fixedly arranged on the second movable platen 34 and telescopic devices 39, sliding blocks are arranged on the slide posts 35 in a sliding way, the third movable platen 36 is arranged on the sliding blocks, telescopic devices 39 are arranged between the third movable platen 36 and the second movable platen 34, the telescopic devices 39 are arranged as hydraulic telescopic adjusting mechanisms, and the bearing seats 37 are symmetrically arranged in two.

The more stable sliding structure of the third movable platen 36 is that two slide ways are provided on each slide post 35, and the two slide ways are adjacently disposed.

In another embodiment, when the whole equipment is used as a whole system to perform control action in a unified way, all driving components need to be connected to a controller, and a powder adding motor 28 and a first movable platen motor 311 for driving a gear to rotate on a rack are set as servo motors; the powder pouring motor 38 is set as a stepping motor; the second moving platen motor 310 driving the second moving platen 34 is provided as a stepping motor. Therefore, the control is more convenient, the use is smoother, the working efficiency is higher, and the overall quality can be controlled.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. A large pipe diameter plastic-coated steel pipe powder pouring groove is characterized in that: comprises a groove body (11), a supporting plate (12), a reinforcing shaft (13), a baffle plate (14), a connecting shaft (15) and a flattening device (16); the groove body (11) is integrally arranged in a trapezoid shape, and comprises two parts, namely a trapezoid groove at the top and an arc groove at the bottom, which are integrally arranged; the bottom of the groove body (11) is provided with a supporting plate (12), the bottom of the supporting plate (12) is provided with a semicircular reinforcing shaft (13), one end of the reinforcing shaft (13) is connected with a cylindrical connecting shaft (15), a partition plate (14) with a matched section shape is arranged between the connecting shaft (15) and the groove body (11) and the supporting plate (12), and a flattening device (16) is arranged on a notch at the top of the groove body (11) in a sliding connection mode.

2. The large-diameter plastic coated steel pipe powder pouring tank as claimed in claim 1, wherein: the supporting plate (12) is bent into a wavy shape, a hole is formed in the bent part of the plate, one end of the supporting plate (12) is fixedly connected with the partition plate (14), the top of the supporting plate is fixedly connected with the groove body (11) at the hole, a connecting plate (17) is fixedly connected to the side face of the supporting plate, and the connecting plate (17) is fixedly connected with the reinforcing shaft (13).

3. The large-diameter plastic coated steel pipe powder pouring tank as claimed in claim 2, wherein: the bottom of the partition plate (14) is provided with a through hole, and the reinforcing shaft (13) is inserted into the through hole.

4. The large-diameter plastic coated steel pipe powder pouring tank as claimed in claim 1, wherein: the flattening device (16) comprises a flattening inner plate (161), an outer clamping plate (162), a connecting clamping shaft (163), a clamping groove (164) and a pin hole (165); the flattening inner plate (161) is a trapezoid plate which is matched with the trapezoid groove in the groove body (11) firstly and comprises an inner part of the groove body (11) and an outer part exceeding the groove body (11); an outer clamping plate (162) is connected and arranged on the outer side of the flattening inner plate (161), and the outer clamping plate (162) is in sliding connection with a chute formed by the flattening inner plate (161) on the chute edge of the chute body (11); the top of the flattening inner plate (161) is connected with a connecting clamping shaft (163), the connecting clamping shaft (163) is provided with a clamping groove (164), and the clamping groove (164) is provided with a pin hole (165).

5. The large-diameter plastic coated steel pipe powder pouring tank as claimed in claim 4, wherein: the inner portion of the flattening inner plate (161) is obliquely arranged.

6. The large-diameter plastic coated steel pipe powder pouring tank as claimed in claim 1, wherein: a scale is arranged on the inner side surface of the groove body (11).