CN113117985B - Anticorrosive pipeline glass inside lining ground coat processing apparatus - Google Patents

Abstract

The invention relates to the field of anti-corrosion pipes, in particular to a device for treating a glass lining ground coat of an anti-corrosion pipeline. The technical problem to be solved by the invention is as follows: provides a device for treating the bottom glaze of the glass lining of the anti-corrosion pipeline. The technical implementation scheme of the invention is as follows: an anticorrosive pipeline glass lining bottom glaze processing device comprises a first working machine bed plate, a supporting foot stool, a second working machine bed plate, an operation control screen and the like; and the upper part of the supporting bottom foot frame is welded with the first working machine tool plate. The invention realizes the effects that the ground glaze on the inner surface of the anti-corrosion pipe is automatically stretched and coated, the glaze is uniformly coated on the inner surface of the anti-corrosion pipe, the coating is controlled, the anti-corrosion pipe is automatically transferred, then the anti-corrosion pipe is fixed again, the glaze on the inner side of the anti-corrosion pipe is uniformly heated in the rotating and vibrating processes, and the anti-corrosion pipe is melted and then flows in a small area, so that the glaze is completely attached to and uniformly distributed on the inner surface of the anti-corrosion pipe after being melted.

Description

Anticorrosive pipeline glass inside lining ground coat processing apparatus

Technical Field

The invention relates to the field of anti-corrosion pipes, in particular to a device for treating a glass lining ground coat of an anti-corrosion pipeline.

Background

The corrosion-resistant pipe is processed by a corrosion-resistant process, is also called as a corrosion-resistant steel pipe and is classified into IPN8710 corrosion resistance and the like.

At present, part of the inner surface of an anticorrosion pipe in the prior art adopts a glass lining to enhance the anticorrosion effect, before the glass lining is blown and molded, a layer of ground glaze is firstly coated on the inner surface of the anticorrosion pipe to ensure the joint degree of the glass lining and the inner surface of the anticorrosion pipe, but in the prior art, the inner surface of the anticorrosion pipe is manually coated, the inner part of the pipeline is deeper and narrower, the manual operation is inconvenient, the consumption of physical strength is large, the efficiency is low, meanwhile, the manual coating cannot ensure the uniformity of the glaze, meanwhile, the anticorrosion pipe is in a static state in the manual coating process, namely, the glaze can naturally and slowly flow downwards under the action of gravity, further, the glaze can be accumulated on the side, close to the ground, of the inner surface of the anticorrosion pipe after coating, the glaze is lack of the glaze on the side, far away from the ground, and the glaze is enhanced in the subsequent heating process of the anticorrosion pipe, and the problem of the accumulation of the glaze is more serious, the glass lining of the anti-corrosion pipeline cannot be tightly attached to the anti-corrosion pipe at the position with less glaze, and the glaze is accumulated at the position with more glaze.

Aiming at the problems, a device for processing the bottom glaze of the glass lining of the anti-corrosion pipeline is provided.

Disclosure of Invention

In order to overcome the defects that in the prior art, a glass lining is adopted on the inner surface of a part of anticorrosive pipe to enhance the anticorrosive effect, a layer of ground glaze is required to be coated on the inner surface of the anticorrosive pipe to ensure the joint degree of the glass lining and the inner surface of the anticorrosive pipe before the glass lining is blown and molded, but in the prior art, the ground glaze is manually coated on the inner surface of the anticorrosive pipe, the inner part of the pipe is deep and narrow, the manual operation is inconvenient, the consumption of physical strength is large, the efficiency is low, meanwhile, the glaze cannot be ensured to be uniform by manual coating, meanwhile, the anticorrosive pipe is in a static state in the manual coating process, namely, the glaze can naturally and slowly flow downwards under the action of gravity, the glaze can be accumulated on the side, close to the ground, of the inner surface of the anticorrosive pipe after coating, the glaze is lack of the glaze on the side, far away from the ground, and the melting fluidity of the glaze is enhanced in the subsequent heating process of the anticorrosive pipe, frit accumulational problem is more serious, leads to anticorrosive pipeline glass inside lining can't closely laminate with anticorrosive pipe in the position that frit is few, causes frit to pile up extravagant shortcoming in the position that frit is many, and the technical problem that solve is: provides a device for treating the bottom glaze of the glass lining of the anti-corrosion pipeline.

The technical implementation scheme of the invention is as follows: the utility model provides an anticorrosive pipeline glass inside lining ground coat processing apparatus, including:

a first working machine bed plate;

the upper part of the supporting bottom foot frame is welded with the first working machine tool plate;

a second working machine bed plate, wherein the lower part of the second working machine bed plate is welded with the support bottom bracket;

an operation control screen;

the lower part of the glazing system is connected with the first working machine tool plate;

the lower part of the bearing rotating system is connected with the first working machine tool plate;

and the uniform distribution system is connected with the operation control screen, and the lower part of the uniform distribution system is connected with the second working machine tool plate.

As a preferred technical scheme of the invention, the glazing system comprises:

a glaze storage box;

the upper part of the first supporting base frame is connected with the glaze storage box through bolts, and the lower part of the first supporting base frame is connected with the first working machine tool plate;

the elastic conveying pipe is inserted into the glaze storage box;

the connecting pipe is connected with the elastic conveying pipe;

the hard elastic pipe is connected with the connecting pipe;

the feeding spray head is connected with the hard elastic pipe;

the inner side of the control lantern ring is contacted with the hard elastic pipe;

the control turntable is fixedly connected with the control lantern ring;

the first rotating shaft rod is fixedly connected with the control turntable;

the first flat gear, the first flat gear axle center and first spindle lever go on building in;

the connecting column is fixedly connected with the control turntable;

the feeding brush is fixedly connected with the connecting column;

the connecting bearing plate is in rotary connection with the control turntable;

the first electric telescopic column is connected with the connecting bearing plate;

the second electric telescopic column is connected with the connecting bearing plate;

the first fixed frame plate is connected with the first electric telescopic column and the second electric telescopic column in sequence, and the lower portion of the first fixed frame plate is connected with the first working machine tool plate.

As a preferred technical scheme of the invention, the bearing and rotating system comprises:

a first power motor;

the second rotating shaft rod is fixedly connected with the output shaft of the first power motor;

the upper part of the second supporting base frame is connected with the first power motor through a bolt;

the second fixed frame plate is rotationally connected with the second rotating shaft rod, and the lower part of the second fixed frame plate is welded with the first working machine bed plate;

the inner side of the bearing conveyor belt is in transmission connection with the second rotating shaft rod;

the outer surface of the third rotating shaft rod is in transmission connection with the bearing conveyor belt;

the first electric telescopic rod is rotatably connected with the third rotating shaft rod;

the second electric telescopic rod is rotatably connected with the third rotating shaft rod;

the outer surface of the electric rotating shaft column is sequentially connected with the first electric telescopic rod and the second electric telescopic rod;

the third fixed frame plate is connected with the electric rotating shaft column, and the lower part of the third fixed frame plate is welded with the first working machine bed plate;

the fourth fixed frame plate is connected with the electric rotating shaft column, and the lower part of the fourth fixed frame plate is welded with the first working machine bed plate;

the lower part of the third supporting base frame is welded with the bed plate of the first working machine;

the lower part of the second power motor is connected with a third supporting base frame through a bolt;

the elastic telescopic rotating shaft rod is fixedly connected with an output shaft of the second power motor;

the first bearing frame plate is rotatably connected with the elastic telescopic rotating shaft rod, and the lower part of the first bearing frame plate is welded with the first working machine bed plate;

the axis of the limiting elliptic plate is fixedly connected with the elastic telescopic rotating shaft rod;

the axle center of the inner fluted disc is fixedly connected with the elastic telescopic rotating shaft rod;

the limiting fork plate is contacted with the limiting elliptic plate;

first electric putter, first electric putter is connected with spacing fork board, and first electric putter is connected with the fixed frame plate of second.

As a preferred technical scheme of the invention, the uniform distribution system comprises:

the lower part of the fifth fixed frame plate is welded with the second working machine bed plate;

the second electric push rod is connected with the fifth fixed frame plate;

the heating strip is connected with the second electric push rod;

the lower part of the fourth supporting base frame is welded with the bed plate of the second working machine;

the lower part of the third power motor is connected with a fourth supporting base frame through a bolt;

the fourth rotating shaft rod is fixedly connected with an output shaft of the third power motor;

the axle center of the second flat gear is fixedly connected with the fourth rotating shaft rod;

the axle center of the third flat gear is fixedly connected with the fourth rotating shaft rod;

the second bearing frame plate is rotatably connected with the fourth rotating shaft rod, and the lower part of the second bearing frame plate is welded with the second working machine bed plate;

the third bearing frame plate is rotatably connected with the fourth rotating shaft rod, and the lower part of the third bearing frame plate is welded with the second working machine bed plate;

the first fixed rotating mechanism is in transmission connection with the second flat gear, and the lower part of the first fixed rotating mechanism is connected with the second working machine tool plate;

the second fixed rotating mechanism is in transmission connection with the third spur gear, and the lower part of the second fixed rotating mechanism is connected with the second working machine tool plate;

the lower part of the fixed top plate is sequentially connected with the first fixed rotating mechanism and the second fixed rotating mechanism;

the fixed frame is connected, and the fixed frame is welded with the fixed top plate;

the first vibration motor is connected with the fixed top plate through bolts;

and the lower part of the second vibration motor is connected with a second working machine bed plate through bolts.

As a preferable aspect of the present invention, the first fixed rotating mechanism includes:

the lower part of the first mounting support column is welded with the second working machine bed plate;

the first arc-shaped sliding rail is welded with the first mounting support column;

the first arc-shaped sliding strip is connected with the first arc-shaped sliding rail in a sliding manner;

the first arc-shaped gear ring is fixedly connected with the first arc-shaped sliding strip and is meshed with the second flat gear;

the second arc-shaped sliding strip is fixedly connected with the first arc-shaped gear ring;

the second arc-shaped sliding rail is in sliding connection with the second arc-shaped sliding strip;

the first clamping arc-shaped strip is fixedly connected with the first arc-shaped gear ring;

the upper part of the electric lifting column is connected with the fixed top plate through a bolt;

the upper part of the connecting seat is connected with the electric lifting column;

the third arc-shaped sliding rail is welded with the connecting seat;

the third arc-shaped sliding strip is connected with the third arc-shaped sliding rail in a sliding manner;

the second arc-shaped gear ring is fixedly connected with the third arc-shaped sliding strip;

the fourth arc-shaped sliding strip is fixedly connected with the second arc-shaped gear ring;

the fourth arc-shaped sliding rail is in sliding connection with the fourth arc-shaped sliding strip;

the second clamping arc-shaped strip is fixedly connected with the second arc-shaped gear ring;

and the second installation supporting column is welded with the second arc-shaped sliding rail, and the lower part of the second installation supporting column is welded with the second working machine bed plate.

As a preferable technical scheme of the invention, the surfaces of the inner sides of the first clamping arc-shaped strip and the second clamping arc-shaped strip, which are contacted with the anti-corrosion pipe, are provided with rubber friction layers.

As a preferred technical solution of the present invention, the first fixed rotating mechanism and the second fixed rotating mechanism have the same structure, and the second flat gear and the third flat gear respectively drive the first fixed rotating mechanism and the second fixed rotating mechanism to operate.

Has the advantages that: in order to solve the problems that in the prior art, a glass lining is adopted on the inner surface of a part of anticorrosive pipe to enhance the anticorrosive effect, a layer of ground glaze is required to be coated on the inner surface of the anticorrosive pipe to ensure the joint degree of the glass lining and the inner surface of the anticorrosive pipe before the glass lining is blown and molded, but in the prior art, the ground glaze is manually coated on the inner surface of the anticorrosive pipe, the inner part of the pipe is deep and narrow, the manual operation is inconvenient, the consumption of physical strength is large, the efficiency is low, meanwhile, the glaze cannot be ensured to be uniform by manual coating, meanwhile, the anticorrosive pipe is in a static state in the manual coating process, namely, the glaze can naturally and slowly flow downwards under the action of gravity, the glaze can be accumulated on the side, close to the ground, of the inner surface of the anticorrosive pipe after coating, the glaze is lack of the glaze on the side, far away from the ground, and the glaze melting fluidity is enhanced in the subsequent heating process of the anticorrosive pipe, and the glaze is accumulated more serious, the problem that the glass lining of the anti-corrosion pipeline cannot be tightly attached to the anti-corrosion pipe at the position with less glaze and the glaze is accumulated and wasted at the position with more glaze is caused;

the glazing system is designed, the bearing rotating system and the uniform distribution system are designed, when the glaze-coating system is used, an anti-corrosion pipe to be processed is fixed above the bearing rotating system, then the glazing system is controlled to stretch into the inner side of the anti-corrosion pipe, the bearing rotating system is controlled to drive the glazing system to operate to coat glaze on the inner side of the anti-corrosion pipe, meanwhile, the bearing rotating system drives the anti-corrosion pipe to rotate reversely to enable the coating to be more uniform, after the coating is finished, the bearing rotating system is controlled to operate to convey the anti-corrosion pipe to the uniform distribution system, then the uniform distribution system controls the glaze on the inner side of the anti-corrosion pipe to be heated, the glaze is completely attached to the inner wall of the anti-corrosion pipe, the anti-corrosion pipe is driven to rotate and vibrate, and the glaze on the inner side of the anti-corrosion pipe is enabled to be more uniform;

the automatic stretching of having realized the internal surface ground coat of anticorrosive pipe stretches into to apply paint with a brush, makes the frit evenly apply paint with a brush at the internal surface of anticorrosive pipe to the control is applied paint with a brush and is bored anticorrosive pipe again and carry out the automatic transfer, then fixes again to anticorrosive pipe, and anticorrosive pipe carries out the even heating to the frit of its inboard at the in-process that rotates and vibrate, makes it melt after carrying out the small area flow and make the frit melt the effect that the back and the complete laminating of anticorrosive pipe internal surface adhere to and evenly distributed.

Drawings

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

FIG. 2 is a schematic perspective view of the glazing system of the present invention;

FIG. 3 is a schematic perspective view of a portion of the glazing system of the present invention;

FIG. 4 is a perspective view of the bearing and rotating system of the present invention;

FIG. 5 is a schematic view of a first three-dimensional structure of the uniform distribution system of the present invention;

FIG. 6 is a second perspective view of the uniform distribution system of the present invention;

FIG. 7 is a first perspective view of the first fixed rotating mechanism of the present invention;

fig. 8 is a schematic diagram of a second perspective structure of the first fixed rotating mechanism of the present invention.

Labeled as: 1-a first working machine bed plate, 2-a supporting foot stool, 3-a second working machine bed plate, 4-an operation control screen, 5-a glazing system, 6-a bearing rotating system, 7-an evenly distributed system, 501-a glaze storage tank, 502-a first supporting base frame, 503-an elastic delivery pipe, 504-a connection pipe, 505-a hard elastic pipe, 506-a loading nozzle, 507-a control collar, 508-a control turntable, 509-a first rotating shaft rod, 5010-a first spur gear, 5011-an engagement column, 5012-a loading brush, 5013-an engagement bearing plate, 5014-a first electric telescopic column, 5015-a second electric telescopic column, 5016-a first fixed frame plate, 601-a first power motor, 602-a second rotating shaft rod, 603-a second supporting base frame, 604-a second fixed frame plate, 605-a carrying conveyor belt, 606-a third rotating shaft rod, 607-a first electric telescopic rod, 608-a second electric telescopic rod, 609-an electric rotating shaft column, 6010-a third fixed frame plate, 6011-a fourth fixed frame plate, 6012-a third supporting base frame, 6013-a second power motor, 6014-an elastic telescopic rotating shaft rod, 6015-a first bearing frame plate, 6016-a limiting elliptic plate, 6017-an internal toothed disc, 6018-a limiting fork plate, 6019-a first electric push rod, 701-a fifth fixed frame plate, 702-a second electric push rod, 703-a heating bar, 704-a fourth supporting base frame, 705-a third power motor, 706-a fourth rotating shaft rod, 707-a second pinion, 708-a third pinion, 708-a second bearing frame plate, 7010-third bearing frame plate, 7011-first fixed rotating mechanism, 7012-second fixed rotating mechanism, 7013-fixed top plate, 7014-engagement fixing frame, 7015-first vibration motor, 7016-second vibration motor, 701101-first installation support column, 701102-first arc slide rail, 701103-first arc slide bar, 701104-first arc toothed ring, 701105-second arc slide bar, 701106-second arc slide rail, 701107-first clamping arc bar, 701108-electric lifting column, 701109-engagement seat, 701110-third arc slide rail, 701111-third arc slide bar, 701112-second arc toothed ring, 701113-fourth arc slide bar, 701114-fourth arc slide rail, 701115-second clamping arc bar, 701116-second installation support column.

Detailed Description

The invention is described in detail below with reference to the drawings and specific examples, but the invention is not limited thereto.

Example 1

An anti-corrosion pipeline glass lining ground coat processing device is shown in figures 1-8 and comprises a first working machine bedplate 1, a supporting bottom underframe 2, a second working machine bedplate 3, an operation control screen 4, a glazing system 5, a bearing rotating system 6 and an even distribution system 7; the upper part of the supporting foot stool 2 is welded with the bed plate 1 of the first working machine; the lower part of the bed plate 3 of the second working machine is welded with a supporting foot stool 2; the lower part of the glazing system 5 is connected with a first working machine bed plate 1; the lower part of the bearing and rotating system 6 is connected with a first working machine bed plate 1; the uniform distribution system 7 is connected with the operation control screen 4, and the lower part of the uniform distribution system 7 is connected with the second working machine bed plate 3.

The working principle is as follows: when the device for treating the bottom glaze on the glass lining of the anti-corrosion pipeline is used, the device is stably fixed to a working plane, then a power supply is connected externally, a control device of an operation control screen 4 is manually opened to operate, then an anti-corrosion pipe to be treated is manually fixed above a bearing rotating system 6, then a glazing system 5 is controlled to extend into the inner side of the anti-corrosion pipe, the bearing rotating system 6 is controlled to drive the glazing system 5 to operate to coat glaze on the inner side of the anti-corrosion pipe, meanwhile, the bearing rotating system 6 drives the anti-corrosion pipe to rotate reversely to enable the coating to be more uniform, after the coating is finished, the bearing rotating system 6 is controlled to operate to transmit the anti-corrosion pipe to a uniform distribution system 7, and then the uniform distribution system 7 controls the glaze on the inner side of the anti-corrosion pipe to heat, so that the glaze is completely attached to the inner wall of the anti-corrosion pipe, and simultaneously drives the anti-corrosion pipe to rotate and vibrate, so that the glaze inside of the anti-corrosion pipe is more uniform, realized stretching into the automation of ground coat to anticorrosive pipe internal surface and applying paint with a brush, made the frit evenly apply paint with a brush at anticorrosive pipe internal surface to control is applied paint with a brush and is bored the anticorrosive pipe again and carry out the automatic transfer, then fixes again anticorrosive pipe, and anticorrosive pipe carries out the even heating at the frit of its inboard at the in-process that rotates and vibrate, makes it melt after carry out the small size flow make the frit melt with the effect of anticorrosive pipe internal surface laminating adhesion and evenly distributed completely.

The glazing system 5 comprises a glaze storage box 501, a first supporting base frame 502, an elastic conveying pipe 503, a connecting pipe 504, a hard elastic pipe 505, a feeding nozzle 506, a control lantern ring 507, a control turntable 508, a first rotating shaft rod 509, a first flat gear 5010, an engagement column 5011, a feeding brush 5012, an engagement bearing plate 5013, a first electric telescopic column 5014, a second electric telescopic column 5015 and a first fixed frame plate 5016; the upper part of the first supporting base frame 502 is connected with the glaze storage box 501 through bolts, and the lower part of the first supporting base frame 502 is connected with the first working machine bed plate 1; the elastic conveying pipe 503 is inserted into the glaze material storage tank 501; the connecting pipe 504 is connected with the elastic conveying pipe 503; the hard elastic tube 505 is connected with the connecting tube 504; the feeding spray head 506 is connected with the hard elastic pipe 505; the inner side of the control sleeve 507 is contacted with the hard elastic tube 505; the control turntable 508 is fixedly connected with the control lantern ring 507; the first rotating shaft 509 is fixedly connected with the control turntable 508; the axle center of the first flat gear 5010 is fixedly connected with the first rotating shaft rod 509; the connecting column 5011 is fixedly connected with the control turntable 508; the feeding brush 5012 is fixedly connected with the connecting column 5011; the connecting bearing plate 5013 is in rotational connection with the control turntable 508; the first electric telescopic column 5014 is connected with the connecting bearing plate 5013; the second electric telescopic column 5015 is connected with the connecting bearing plate 5013; the first fixed frame plate 5016 is sequentially connected with a first electric telescopic column 5014 and a second electric telescopic column 5015, and the lower portion of the first fixed frame plate 5016 is connected with the first working machine bedplate 1.

After the anti-corrosion pipe is fixed above the bearing rotating system 6, the first electric telescopic column 5014 and the second electric telescopic column 5015 are controlled to be pushed out, the first electric telescopic column 5014 and the second electric telescopic column 5015 drive the connecting bearing plate 5013 to move towards the direction close to the anti-corrosion pipe, then the connecting bearing plate 5013 drives the connected parts to synchronously move, namely to synchronously move to the inner side of the anti-corrosion pipe, then the first flat gear 5010 moves to the position meshed with the inner toothed disc 6017, namely the inner toothed disc 6017 drives the first flat gear 5010 to rotate, then the valve inside the glaze storage box 501 is controlled to be opened through the operation control screen 4, namely glaze inside the glaze storage box 501 flows out from the elastic conveying pipe 503, then the glaze sequentially passes through the connecting pipe 504 and the hard elastic pipe 505 and is sprayed out from the opening of the feeding nozzle 506, namely the glaze is sprayed out to the top of the feeding brush 5012, at the moment, the top of the feeding brush 5012 is contacted with the inner surface of the anti-corrosion pipe, while the first spur gear 5010 drives the control dial 508 to rotate via the first spindle rod 509, then the control turntable 508 drives the connecting column 5011 and the feeding brush 5012 to rotate, meanwhile, the control turntable 508 drives the feeding spray head 506 to do circular motion through the control lantern ring 507, that is, the feeding nozzle 506 and the feeding brush 5012 keep synchronous rotation, that is, in the process that the feeding brush 5012 is attached to the inner wall of the anticorrosion pipe to rotate, the feeding nozzle 506 continuously sprays materials, then, as the first electric telescopic post 5014 and the second electric telescopic post 5015 are slowly extended and pushed out, the feeding brush 5012 and the feeding nozzle 506 are also continuously moved in the direction of the corrosion-resistant pipe during the rotation, the first flat gear 5010 is constantly kept engaged with the internal toothed disc 6017, the continuous rotation of the feeding brush 5012 and the feeding nozzle 506 is ensured until the feeding brush 5012 brushes the inner wall of the anti-corrosion pipe once, and the painting of the glaze on the inner wall of the anti-corrosion pipe is completed.

The bearing and rotating system 6 comprises a first power motor 601, a second rotating shaft rod 602, a second supporting base frame 603, a second fixed frame plate 604, a bearing conveyor belt 605, a third rotating shaft rod 606, a first electric telescopic rod 607, a second electric telescopic rod 608, an electric rotating shaft column 609, a third fixed frame plate 6010, a fourth fixed frame plate 6011, a third supporting base frame 6012, a second power motor 6013, an elastic telescopic rotating shaft rod 6014, a first bearing frame plate 6015, a limiting elliptic plate 6016, an internal toothed disc 6017, a limiting fork plate 6018 and a first electric push rod 6019; the second rotating shaft rod 602 is fixedly connected with an output shaft of the first power motor 601; the upper part of the second supporting base frame 603 is connected with a first power motor 601 through a bolt; the second fixed frame plate 604 is rotatably connected with the second rotating shaft rod 602, and the lower part of the second fixed frame plate 604 is welded with the first working machine bed plate 1; the inner side of the carrier belt 605 is in transmission connection with the second rotating shaft 602; the outer surface of the third rotating shaft rod 606 is in transmission connection with the bearing conveyor belt 605; the first electric telescopic rod 607 is rotatably connected with the third rotating shaft 606; the second electric telescopic rod 608 is rotatably connected with the third rotating shaft 606; the outer surface of the electric rotating shaft column 609 is sequentially connected with a first electric telescopic rod 607 and a second electric telescopic rod 608; the third fixed frame plate 6010 is connected with the electric rotating shaft column 609, and the lower part of the third fixed frame plate 6010 is welded with the first working machine bed plate 1; the fourth fixed frame plate 6011 is connected with the electric rotating shaft column 609, and the lower part of the fourth fixed frame plate 6011 is welded with the first working machine bed plate 1; the lower part of the third supporting base frame 6012 is welded with the first working machine bed plate 1; the lower part of the second power motor 6013 is bolted to a third supporting base frame 6012; the elastic telescopic rotating shaft 6014 is fixedly connected with an output shaft of a second power motor 6013; the first bearing frame plate 6015 is rotatably connected with the elastic telescopic rotating shaft rod 6014, and the lower part of the first bearing frame plate 6015 is welded with the first working machine bed plate 1; the axis of the limiting elliptic plate 6016 is fixedly connected with the elastic telescopic rotating shaft rod 6014; the axle center of the inner fluted disc 6017 is fixedly connected with the elastic telescopic rotating shaft 6014; the limiting fork plate 6018 is in contact with the limiting oval plate 6016; the first electric push rod 6019 is connected to the position-limiting fork 6018, and the first electric push rod 6019 is connected to the second fixing frame plate 604.

Firstly, the anticorrosion pipe is placed on the top of the bearing conveyor belt 605, then due to the gravity of the anticorrosion pipe, the bearing conveyor belt 605 between the second rotating shaft rod 602 and the third rotating shaft rod 606 is tightened, then the power supply of the first power motor 601 is controlled to be switched on, then the first power motor 601 drives the second rotating shaft rod 602 to rotate, the second rotating shaft rod 602 drives the bearing conveyor belt 605 to rotate, then the bearing conveyor belt 605 drives the third rotating shaft rod 606 to rotate under the tight state, further the bearing conveyor belt 605 drives the anticorrosion pipe to rotate under the synchronous rotation of the third rotating shaft rod 606 and the second rotating shaft rod 602, then the first electric push rod 6019 is controlled to contract, further the first electric push rod 6019 drives the limit fork 6018 to move, then the limit fork 6018 leaves the limit elliptic plate 6016, at this time, the limit elliptic plate 6016 is not blocked by the limit fork 6018, then the elasticity of the elastic telescopic rotating shaft 6014 is not limited any more, namely, the elastically stretchable spindle 6014 is stretched, that is, the elastically stretchable spindle 6014 drives the inner toothed disc 6017 to extend into the inner side of the anticorrosive pipe, after the elastically stretchable spindle 6014 is fully stretched, the inner toothed disc 6017 moves to the opening on the other side of the anticorrosive pipe, then the power supply of the second power motor 6013 is controlled to be turned on, that is, the second power motor 6013 drives the elastically stretchable spindle 6014 to rotate, the elastically stretchable spindle 6014 drives the inner toothed disc 6017 to rotate, then the glazing system 5 is controlled to operate, that is, when the first pinion 5010 moves towards the inside of the anticorrosive pipe, the first pinion 5010 is firstly embedded into the inner toothed disc 6017, then the inner toothed disc 6017 drives the first pinion 5010 to rotate, and along with the continuous deep movement of the first pinion 5010 towards the inside of the anticorrosive pipe, that is, the first pinion 5010 keeps in a state of being meshed with the inner toothed disc 6017, the first pinion 5010 moves the inner toothed disc 6017 towards a direction close to the second power motor 6013, namely, the internal toothed disc 6017 moves to reset in the rotating process to compress the elastically telescopic rotating shaft 6014 again, that is, the elastically telescopic rotating shaft 6014 contracts slowly until the elastically telescopic rotating shaft 6014 contracts to the original length, that is, the glazing system 5 finishes coating the glaze on the inner wall of the anticorrosive pipe, then the first electric push rod 6019 is controlled to push out, that is, the first electric push rod 6019 drives the limit fork 6018 to move to the original position, that is, the limit fork 6018 blocks the limit oval plate 6016, and then the glazing system 5 is controlled to reset, then the electric rotating shaft column 609 is controlled to drive the first electric telescopic rod 607 and the second electric telescopic rod 608 to rotate, that is, the first electric telescopic rod 607 and the second electric telescopic rod 608 drive the third rotating shaft 606 to move, that the third rotating shaft 606 drives one side of the bearing conveyor belt 605 to move towards the direction close to the uniform distribution system 7, the first electric telescopic rod 607 and the second electric telescopic rod 608 are extended, then one side of the bearing conveyor belt 605, which is driven by the third rotating shaft rod 606, contacts the uniform distribution system 7, and at the same time, the bearing conveyor belt 605 is in a tensioned and inclined state, so that the anticorrosive pipe at the top of the bearing conveyor belt 605 rolls downwards to the uniform distribution system 7 due to gravity, and the bearing of the anticorrosive pipe and the control of the operation of the device are completed.

The uniform distribution system 7 comprises a fifth fixed frame plate 701, a second electric push rod 702, a heating strip 703, a fourth supporting base frame 704, a third power motor 705, a fourth rotating shaft rod 706, a second pinion 707, a third pinion 708, a second bearing frame plate 709, a third bearing frame plate 7010, a first fixed rotating mechanism 7011, a second fixed rotating mechanism 7012, a fixed top plate 7013, a linking fixed frame 7014, a first vibrating motor 7015 and a second vibrating motor 7016; the lower part of the fifth fixed frame plate 701 is welded with a second working machine bed plate 3; the second electric push rod 702 is connected with the fifth fixed frame plate 701; the heating bar 703 is connected with the second electric push rod 702; the lower part of the fourth supporting base frame 704 is welded with the bed plate 3 of the second working machine; the lower part of the third power motor 705 is connected with a fourth supporting base frame 704 through a bolt; the fourth rotating shaft rod 706 is fixedly connected with an output shaft of the third power motor 705; the axle center of the second pinion 707 is fixedly connected with the fourth rotating shaft rod 706; the axle center of the third pinion 708 is fixedly connected with the fourth rotating shaft lever 706; the second bearing frame plate 709 is rotatably connected with the fourth rotating shaft rod 706, and the lower part of the second bearing frame plate 709 is welded with the second working machine bed plate 3; the third bearing frame plate 7010 is rotationally connected with the fourth rotating shaft rod 706, and the lower part of the third bearing frame plate 7010 is welded with the second working machine bed plate 3; the first fixed rotating mechanism 7011 is in transmission connection with the second flat gear 707, and the lower part of the first fixed rotating mechanism 7011 is connected with the second working machine bed plate 3; the second fixed rotating mechanism 7012 is in transmission connection with the third spur gear 708, and the lower part of the second fixed rotating mechanism 7012 is connected with the second working machine bedplate 3; the lower part of the fixed top plate 7013 is sequentially connected with a first fixed rotating mechanism 7011 and a second fixed rotating mechanism 7012; the fixed frame 7014 is connected with the fixed top plate 7013 for welding; the first vibration motor 7015 is bolted to the fixed ceiling 7013; the lower part of the second vibrating motor 7016 is connected with the second working machine bed plate 3 through bolts.

Firstly, the anti-corrosion pipe rolls to the inside of the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 along the bearing conveyor 605, then the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 are controlled to clamp the anti-corrosion pipe, then the second electric push rod 702 is controlled to extend out, namely the second electric push rod 702 drives the heating strip 703 to extend into the inside of the anti-corrosion pipe, the power supply of the heating strip 703 is switched on, namely the heating strip 703 starts to generate heat, the heating strip 703 heats the glaze on the inner surface of the anti-corrosion pipe, and simultaneously the power supply of the third power motor 705 is controlled to be switched on, then the third power motor 705 drives the fourth rotating shaft 706 to rotate, namely the fourth rotating shaft 706 drives the second flat gear 707 and the third flat gear 708 to rotate, then the second flat gear 707 and the third flat gear 708 respectively drive the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 to operate, namely the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 drive the anti-corrosion pipe to rotate, the power of the first vibrating motor 7015 and the second vibrating motor 7016 is switched on simultaneously, namely the first vibrating motor 7015 and the second vibrating motor 7016 drive the fixed top plate 7013 and the second working machine bed plate 3 to vibrate respectively, and then drive the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 to vibrate, namely, the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 drive the anticorrosive pipe to rotate and simultaneously drive the anticorrosive pipe to vibrate, and meanwhile, glaze on the inner surface of the anticorrosive pipe is heated, so that the glaze is completely attached to the inner wall of the anticorrosive pipe, and meanwhile, the anticorrosive pipe is driven to rotate and vibrate, and the glaze inside of the anticorrosive pipe is more uniform.

The first fixed rotating mechanism 7011 comprises a first mounting support column 701101, a first arc-shaped slide rail 701102, a first arc-shaped slide bar 701103, a first arc-shaped toothed ring 701104, a second arc-shaped slide bar 701105, a second arc-shaped slide rail 701106, a first clamping arc-shaped bar 701107, an electric lifting column 701108, a connecting seat 701109, a third arc-shaped slide rail 701110, a third arc-shaped slide bar 701111, a second arc-shaped toothed ring 701112, a fourth arc-shaped slide bar 701113, a fourth arc-shaped slide rail 701114, a second clamping arc-shaped bar 701115 and a second mounting support column 701116; the lower part of the first mounting support column 701101 is welded with the second working machine bed plate 3; the first arc-shaped sliding rail 701102 is welded with the first installation supporting column 701101; the first arc-shaped sliding strip 701103 is in sliding connection with the first arc-shaped sliding rail 701102; the first arc-shaped gear ring 701104 is fixedly connected with the first arc-shaped sliding strip 701103, and the first arc-shaped gear ring 701104 is meshed with the second flat gear 707; the second arc-shaped sliding strip 701105 is fixedly connected with the first arc-shaped gear ring 701104; the second arc-shaped slide rail 701106 is in sliding connection with the second arc-shaped slide bar 701105; the first clamping arc-shaped strip 701107 is fixedly connected with the first arc-shaped toothed ring 701104; the upper part of the electric lifting column 701108 is connected with the fixed top plate 7013 through bolts; the upper part of the connecting seat 701109 is connected with an electric lifting column 701108; the third arc-shaped slide rail 701110 is welded with the connecting seat 701109; the third arc-shaped sliding strip 701111 is in sliding connection with the third arc-shaped sliding rail 701110; the second arc-shaped gear ring 701112 is fixedly connected with the third arc-shaped sliding strip 701111; the fourth arc-shaped sliding strip 701113 is fixedly connected with the second arc-shaped gear ring 701112; the fourth arc-shaped slide rail 701114 is in sliding connection with the fourth arc-shaped slide bar 701113; the second clamping arc-shaped strip 701115 is fixedly connected with the second arc-shaped gear ring 701112; the second mounting support column 701116 is welded to the second arc-shaped slide rail 701106, and the lower portion of the second mounting support column 701116 is welded to the second working bedplate 3.

Firstly, the electric lifting column 701108 is controlled to contract upwards, namely, the electric lifting column 701108 drives the joint base 701109, the third arc-shaped sliding rail 701110, the third arc-shaped sliding bar 701111, the second arc-shaped toothed ring 701112, the fourth arc-shaped sliding bar 701113, the fourth arc-shaped sliding rail 701114 and the second clamping arc-shaped bar 701115 to move upwards integrally, namely, a circular space between the second clamping arc-shaped bar 701115 and the first clamping arc-shaped bar 701107 is opened, then the anticorrosion pipe is controlled to roll into the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 along the bearing conveyor belt 605, namely, the anticorrosion pipe rolls to the upper part of the first clamping arc-shaped bar 701107, then the electric lifting column 701108 is controlled to push downwards to realize the downward movement of the second clamping arc-shaped bar 701115, further the second clamping arc-shaped bar 701115 and the first clamping arc-shaped bar 701107 clamp the anticorrosion pipe, and then the second flat gear 707 is controlled to drive the first arc-shaped toothed ring 701104 to rotate, that is, the first arc-shaped toothed ring 701104 slides inside the first arc-shaped sliding rail 701102 and the second arc-shaped sliding rail 701106 through the first arc-shaped sliding bar 701103 and the second arc-shaped sliding bar 701105 respectively to perform a circular motion, and meanwhile, the first arc-shaped toothed ring 701104 cooperates with the second clamping arc-shaped bar 701115 through the first clamping arc-shaped bar 701107 to drive the corrosion protection tube inside the first arc-shaped sliding rail 701102 and the second arc-shaped sliding rail 701106 to rotate, and the corrosion protection tube drives the second arc-shaped toothed ring 701112 to perform a circular motion, and then the second arc-shaped toothed ring 701112 slides inside the third arc-shaped sliding rail 701110 and the fourth arc-shaped sliding rail 359 through the third arc-shaped sliding bar 701111 and the fourth arc-shaped sliding bar 701113 respectively to perform a sliding motion, and further drives the corrosion protection tube to rotate, because the first arc-shaped toothed ring 701104 and the second arc-shaped toothed ring 701112 have the same size, and further the second arc-shaped toothed ring 701112 can drive the third arc-shaped sliding bar 701111 and the fourth arc-shaped sliding bar 701113 to enter the first arc-shaped sliding rail 701102 and the first arc-shaped sliding rail 867 and the second arc-shaped sliding rail 701102 respectively when rotating downwards The inside sliding motion that carries on of two arc slide rails 701106, first arc slide bar 701103 and second arc slide bar 701105 also can enter into third arc slide rail 701110 and fourth arc slide rail 701114 inside and slide, and then realize that first arc ring gear 701104 and second arc ring gear 701112 can mesh with second pinion 707 alternately, realize the continuous rotation of first arc ring gear 701104 and second arc ring gear 701112 promptly, first arc ring gear 701104 and second arc ring gear 701112 clamp through first clamp arc strip 701107 and second clamp arc strip 701115 again and drive the anticorrosive pipe and carry out the continuous rotation.

The surfaces of the inner sides of the first and second clamping arc-shaped strips 701107, 701115, which are in contact with the corrosion protection pipe, are provided with rubber friction layers.

So as to increase the frictional force of the first and second clamping arc-shaped bars 701107 and 701115 contacting the outer surface of the corrosion protection pipe.

The first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 have the same structure, and the second flat gear 707 and the third flat gear 708 drive the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 to operate, respectively.

So that the first fixed rotating mechanism 7011 and the second fixed rotating mechanism 7012 can fix the anti-corrosion pipe at the same time and synchronously drive the anti-corrosion pipe to rotate.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (4)

1. The utility model provides an anticorrosive pipeline glass inside lining ground coat processing apparatus, including:

a first working machine bed plate (1);

the upper part of the supporting bottom foot frame (2) is welded with the first working machine bed plate (1);

a second working machine bed plate (3), wherein the lower part of the second working machine bed plate (3) is welded with a supporting foot stool (2);

it is characterized by also comprising:

an operation control screen (4);

the lower part of the glazing system (5) is connected with a first working machine bed plate (1);

the lower part of the bearing rotating system (6) is connected with the first working machine bed plate (1);

the uniform distribution system (7), the uniform distribution system (7) is connected with the operation control screen (4), and the lower part of the uniform distribution system (7) is connected with the second working machine bed plate (3);

the glazing system (5) comprises:

a glaze storage bin (501);

the upper part of the first supporting base frame (502) is connected with the glaze storage box (501) through bolts, and the lower part of the first supporting base frame (502) is connected with the first working machine bed plate (1);

the elastic conveying pipe (503), the elastic conveying pipe (503) is spliced with the glaze storage box (501);

the connecting pipe (504), the connecting pipe (504) is connected with the elastic conveying pipe (503);

a hard elastic tube (505), wherein the hard elastic tube (505) is connected with the connecting tube (504);

the feeding spray head (506), the feeding spray head (506) is connected with the hard elastic pipe (505);

a control sleeve ring (507), wherein the inner side of the control sleeve ring (507) is contacted with the hard elastic pipe (505);

the control turntable (508), the control turntable (508) is fixedly connected with the control lantern ring (507);

the first rotating shaft rod (509), the first rotating shaft rod (509) is fixedly connected with the control turntable (508);

the first flat gear (5010), the axle center of the first flat gear (5010) is fixedly connected with the first rotating shaft rod (509);

the connecting column (5011), the connecting column (5011) is fixedly connected with the control turntable (508);

the feeding brush (5012) is fixedly connected with the connecting column (5011);

the connecting bearing plate (5013), the connecting bearing plate (5013) is in rotating connection with the control turntable (508);

the first electric telescopic column (5014), the first electric telescopic column (5014) is connected with the connecting bearing plate (5013);

the second electric telescopic column (5015), the second electric telescopic column (5015) is connected with the connecting bearing plate (5013);

the first fixed frame plate (5016), the first fixed frame plate (5016) is sequentially connected with a first electric telescopic column (5014) and a second electric telescopic column (5015), and the lower portion of the first fixed frame plate (5016) is connected with the first working machine bed plate (1);

the bearing and rotating system (6) comprises:

a first power motor (601);

the second rotating shaft rod (602), the second rotating shaft rod (602) is fixedly connected with the output shaft of the first power motor (601);

the upper part of the second supporting base frame (603) is connected with the first power motor (601) through a bolt;

the second fixing frame plate (604), the second fixing frame plate (604) is rotatably connected with the second rotating shaft rod (602), and the lower part of the second fixing frame plate (604) is welded with the first working machine bed plate (1);

the inner side of the bearing conveyor belt (605) is in transmission connection with the second rotating shaft rod (602);

the outer surface of the third rotating shaft rod (606) is in transmission connection with the bearing conveyor belt (605);

the first electric telescopic rod (607), the first electric telescopic rod (607) is connected with the third rotating shaft lever (606) in a rotating way;

the second electric telescopic rod (608), the second electric telescopic rod (608) and the third rotating shaft rod (606) are connected in a rotating mode;

the outer surface of the electric rotating shaft column (609) is sequentially connected with a first electric telescopic rod (607) and a second electric telescopic rod (608);

the third fixing frame plate (6010), the third fixing frame plate (6010) is connected with the electric rotating shaft column (609), and the lower portion of the third fixing frame plate (6010) is welded with the first working machine bed plate (1);

the fourth fixing frame plate (6011), the fourth fixing frame plate (6011) is connected with the electric rotating shaft column (609), and the lower portion of the fourth fixing frame plate (6011) is welded with the first working machine bed plate (1);

a third supporting base frame (6012), wherein the lower part of the third supporting base frame (6012) is welded with the first working machine bed plate (1);

a second power motor (6013), wherein the lower part of the second power motor (6013) is in bolted connection with a third supporting base frame (6012);

the elastic telescopic rotating shaft rod (6014), the elastic telescopic rotating shaft rod (6014) is fixedly connected with an output shaft of a second power motor (6013);

the first bearing frame plate (6015), the first bearing frame plate (6015) is rotatably connected with the elastic telescopic rotating shaft rod (6014), and the lower portion of the first bearing frame plate (6015) is welded with the first working machine bed plate (1);

the limiting elliptic plate (6016), the axis of the limiting elliptic plate (6016) is fixedly connected with the elastic telescopic rotating shaft rod (6014);

the inner fluted disc (6017), the axle center of the inner fluted disc (6017) is fixedly connected with the elastic telescopic rotating shaft rod (6014);

the limiting fork plate (6018), the limiting fork plate (6018) is in contact with the limiting elliptic plate (6016);

the first electric push rod (6019), the first electric push rod (6019) is connected with the limiting fork plate (6018), and the first electric push rod (6019) is connected with the second fixed frame plate (604);

the uniform distribution system (7) comprises:

a fifth fixed frame plate (701), wherein the lower part of the fifth fixed frame plate (701) is welded with the second working machine bed plate (3);

the second electric push rod (702), the second electric push rod (702) links with fifth fixed shelf (701);

the heating strip (703), the heating strip (703) is connected with second electric push rod (702);

a fourth supporting base frame (704), wherein the lower part of the fourth supporting base frame (704) is welded with the second working machine bed plate (3);

a third power motor (705), wherein the lower part of the third power motor (705) is in bolted connection with a fourth supporting base frame (704);

the fourth rotating shaft rod (706), the fourth rotating shaft rod (706) is fixedly connected with the output shaft of the third power motor (705);

the axle center of the second flat gear (707) is fixedly connected with the fourth rotating shaft rod (706);

the axle center of the third gear (708) is fixedly connected with the fourth rotating shaft rod (706);

the second bearing frame plate (709), the second bearing frame plate (709) is in rotating connection with the fourth rotating shaft rod (706), and the lower part of the second bearing frame plate (709) is welded with the second working machine bed plate (3);

the third bearing frame plate (7010), the third bearing frame plate (7010) and the fourth rotating shaft rod (706) are rotatably connected, and the lower part of the third bearing frame plate (7010) is welded with the second working machine bed plate (3);

the first fixed rotating mechanism (7011), the first fixed rotating mechanism (7011) is in transmission connection with the second flat gear (707), and the lower part of the first fixed rotating mechanism (7011) is connected with the second working machine bed plate (3);

the second fixed rotating mechanism (7012), the second fixed rotating mechanism (7012) is in transmission connection with the third spur gear (708), and the lower part of the second fixed rotating mechanism (7012) is connected with the second working machine bedplate (3);

the lower part of the fixed top plate (7013) is sequentially connected with a first fixed rotating mechanism (7011) and a second fixed rotating mechanism (7012);

the fixed frame (7014) is jointed, and the fixed frame (7014) is welded with the fixed top plate (7013);

the first vibration motor (7015), the first vibration motor (7015) and the fixed top plate (7013) are in bolted connection;

and a second vibration motor (7016), wherein the lower part of the second vibration motor (7016) is connected with a second working machine bedplate (3) through bolts.

2. The device for treating the ground glaze on the glass liner of the anti-corrosion pipeline as claimed in claim 1, which is characterized in that: the first fixed rotation mechanism (7011) includes:

the lower part of the first mounting support column (701101) is welded with the second working machine bed plate (3);

the first arc-shaped sliding rail (701102), the first arc-shaped sliding rail (701102) is welded with the first mounting support column (701101);

a first arcuate slider bar (701103), the first arcuate slider bar (701103) being slidably connected to the first arcuate slide rail (701102);

the first arc-shaped gear ring (701104), the first arc-shaped gear ring (701104) is fixedly connected with the first arc-shaped sliding strip (701103), and the first arc-shaped gear ring (701104) is meshed with the second flat gear (707);

the second arc-shaped sliding strip (701105), the second arc-shaped sliding strip (701105) is fixedly connected with the first arc-shaped toothed ring (701104);

the second arc-shaped sliding rail (701106), the second arc-shaped sliding rail (701106) is connected with the second arc-shaped sliding bar (701105) in a sliding way;

the first clamping arc-shaped strip (701107), the first clamping arc-shaped strip (701107) is fixedly connected with the first arc-shaped toothed ring (701104);

the upper part of the electric lifting column (701108) is connected with a fixed top plate (7013) through a bolt;

the upper part of the connecting seat (701109) is connected with an electric lifting column (701108);

the third arc-shaped sliding rail (701110), the third arc-shaped sliding rail (701110) is welded with the connecting seat (701109);

a third arcuate slider bar (701111), the third arcuate slider bar (701111) being slidably connected to the third arcuate rail (701110);

the second arc-shaped gear ring (701112), the second arc-shaped gear ring (701112) is fixedly connected with the third arc-shaped sliding strip (701111);

the fourth arc-shaped sliding strip (701113), the fourth arc-shaped sliding strip (701113) is fixedly connected with the second arc-shaped gear ring (701112);

a fourth arc-shaped slide rail (701114), the fourth arc-shaped slide rail (701114) is connected with the fourth arc-shaped slide bar (701113) in a sliding way;

the second clamping arc-shaped strip (701115), the second clamping arc-shaped strip (701115) is fixedly connected with the second arc-shaped toothed ring (701112);

and the second installation supporting column (701116), the second installation supporting column (701116) and the second arc-shaped sliding rail (701106) are welded, and the lower part of the second installation supporting column (701116) is welded with the second working machine bed plate (3).

3. The device for treating the ground glaze on the glass liner of the anti-corrosion pipeline as claimed in claim 2, which is characterized in that: the surfaces of the inner sides of the first clamping arc-shaped strip (701107) and the second clamping arc-shaped strip (701115) which are contacted with the anti-corrosion pipe are provided with rubber friction layers.

4. The device for treating the ground glaze on the glass lining of the anti-corrosion pipeline according to claim 3, which is characterized in that: the first fixed rotating mechanism (7011) and the second fixed rotating mechanism (7012) have the same structure, and the second flat gear (707) and the third flat gear (708) drive the first fixed rotating mechanism (7011) and the second fixed rotating mechanism (7012) to operate respectively.

Images