CN115815240A

CN115815240A - Slag remover capable of automatically cleaning water conservancy pipeline slag soil and use method thereof

Info

Publication number: CN115815240A
Application number: CN202211563928.1A
Authority: CN
Inventors: 谢彬; 郑君; 唐条凤
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-12-07
Filing date: 2022-12-07
Publication date: 2023-03-21

Abstract

The application discloses a slag remover capable of automatically cleaning water conservancy pipeline slag soil and a using method thereof, the slag remover comprises a slag conveying mechanism and a slag removing rod which is arranged in a hollow structure, and an inner cylinder is fixedly arranged in the hollow part of the slag removing rod; the slag conveying mechanism comprises a plurality of slag removing shafts which are arranged around the inner cylinder and distributed in an annular shape at equal intervals; the side surfaces of the slag removing shaft are uniformly and fixedly connected with a plurality of scraping and moving blocks which are arranged in an arc-shaped structure; and the slag removing shaft drives the cutting moving block to move along the inner wall of the pipeline, and simultaneously, the slag is conveyed out. In the application, when the inner wall of the water conservancy pipeline is effectively scraped, residues can be cleaned out of the pipeline in time, so that subsequent work can be carried out smoothly, and the cleaning efficiency and effect are improved; and the scraping and conveying are synchronous, so that the continuous operation of slag removal is realized.

Description

Slag remover capable of automatically cleaning water conservancy pipeline slag soil and use method thereof

Technical Field

The application relates to the technical field of slag removing machines, in particular to a slag removing machine capable of automatically cleaning water conservancy pipeline slag soil and a using method thereof.

Background

When the water conservancy pipeline is carried, need carry out timely clearance to realize water conservancy pipeline's continuation work.

The document with the prior art publication number CN111687146A provides an automatic pipeline slag removing device for hydraulic engineering, which can scrape pipeline slag on the inner wall of a pipeline body by using a scraper and fall to the front side of a slag removing push ring when an inner transmission gear and the slag removing push ring synchronously rotate and can move forwards by arranging the scraper at the peripheral end of the slag removing push ring, and the scraped pipeline slag is pushed out by the slag removing push ring.

The automatic slag removing device removes slag through the movement of the slag removing ring, the force is completely on the slag removing ring, the slag removing ring is easy to damage, and the pipeline cannot be timely removed after the slag falls off, so that secondary blockage is easily caused.

In the correlation technique to among the above-mentioned, the inventor thinks when clearing up the water conservancy pipeline, should be when effectively scraping off, the pipeline is cleared up out to the dregs that will scrape down in time to realize going on smoothly of follow-up work, improve scarfing cinder efficiency and effect.

In view of the above, a slag remover capable of automatically cleaning water conservancy pipeline slag soil and a use method thereof are provided.

Disclosure of Invention

1. Technical problem to be solved

The application aims to provide the slag remover capable of automatically cleaning the water conservancy pipeline slag soil and the using method thereof, so that the technical problem which can be solved by the exclusive right in the prior art is solved, and the technical effect is realized.

2. Technical scheme

The technical scheme provides a slag remover capable of automatically cleaning water conservancy pipeline slag soil, which comprises a slag removing rod 1 in a hollow structure, wherein an inner cylinder 11 is fixedly arranged in the hollow part of the slag removing rod 1;

the slag conveying mechanism 2 comprises a plurality of slag removing shafts 21, and the plurality of slag removing shafts 21 are arranged around the inner cylinder 11 and distributed at equal intervals in an annular shape; a plurality of scraping and moving blocks 3 are uniformly and fixedly connected to the side surfaces of the slag removing shaft 21, and the scraping and moving blocks 3 are arranged in an arc-shaped structure; the slag removal shaft 21 drives the cutting block 3 to carry out working of the inner wall of the pipeline and simultaneously convey the slag out.

Through adopting above-mentioned technical scheme, through defeated sediment mechanism 2's setting, can effectively strike off water conservancy pipeline at the in-process that uses, clearance that simultaneously can be timely goes out the pipeline to can be for going on more smoothly going on of follow-up work, raise the efficiency and effect.

In a possible embodiment, the distal end of the inner cylinder 11 extends to one side of the distal end of the slag removing rod 1 and is fixedly connected with a connecting column, and the side surface of the inner cylinder 11, which is positioned at the outer part of the slag removing rod 1, is provided with a plurality of inlets 12.

In a possible implementation manner, a machine cavity a101 is formed at the distal end of the connecting column, a first motor 102 is fixedly arranged inside the machine cavity a101, and an output shaft of the first motor 102 penetrates through the inner wall of the machine cavity a101 to extend to the outer side of the connecting column and is fixedly provided with an anti-blocking head 103 which is arranged in a conical structure.

In the above technical scheme, the rotating choke plug 103 can crush the blockage during slag removal.

In a possible embodiment, a plurality of slag guide grooves 1001 arranged in a spiral structure are formed on the side surface of the choke plug 103;

the diameter of the anti-blocking head 103 is larger than that of the inner barrel 11;

a limit groove A1002 is formed in the proximal end face of the anti-blocking head 103, and the limit groove A1002 is arranged in an annular structure;

the inside of the limiting groove A1002 is provided with a guide rail 1003 in a sliding manner, and the guide rail 1003 is fixedly connected to the far end face of the connecting column.

In the above technical solution, the anti-blocking head 103 can convey the residue from the distal end to the proximal end through the slag guide groove 1001 in the process of breaking the blockage.

In a possible implementation mode, a conveying auger 201 is rotatably arranged inside the inner barrel 11, and the conveying auger 201 is matched with the inner diameter of the inner barrel 11;

the distal end of the conveying auger 201 extends to the inlet 12.

In a possible implementation mode, a machine cavity B2001 is opened at the proximal end of the inner cylinder 11, a second motor 2002 is fixedly arranged inside the machine cavity B2001, and an output shaft of the second motor 2002 penetrates through the inner wall of the machine cavity B2001, extends to the inside of the inner cylinder 11, and is coaxially and fixedly connected with the conveying auger 201.

In the above technical solution, when the cutting block 3 performs the working leg movement on the inner wall of the pipe, the cutting block 3 conveys the residue into the inner cylinder 11 through the inlet 12 and conveys the residue out through the conveying auger 201, so that continuous working leg cleaning can be realized.

In a possible embodiment, a driving block 4 is arranged at the far end of the slag removing shaft 21, a slideway 41 is arranged in the middle of the driving block 4, a sliding belt 42 is slidably arranged on the outer wall of the slideway 41, and a plurality of uniformly distributed tooth blocks a43 are fixedly arranged on the outer wall of the sliding belt 42;

the slag removing rod 1 is characterized in that the far end face is provided with a limiting groove B44, a tooth block B is fixedly arranged in the limiting groove B44, and the tooth block A43 is in meshed connection with the tooth block B.

In the above technical solution, the cutting moving block 3 on the slag removal shaft 21 may repeatedly move back and forth along the inner wall of the working channel, so that impurities adhered to the inner wall may be scraped and collected, and the cleaning effect is improved.

In one possible embodiment, the limiting groove B44 is arranged in a figure 8 structure;

the section of the driving block 4 is in a diamond structure, and the size of the driving block 4 is larger than that of the middle intersection of the limiting groove B44.

By adopting the technical scheme, the cutting block 3 can continuously perform cutting operation.

In a possible embodiment, at least one gear cavity 401 is formed inside the driving block 4, a transmission gear 402 is rotatably arranged inside the gear cavity 401, and the transmission gear 402 is engaged with a tooth block C403 fixedly arranged inside the sliding belt 42;

at least one machine cavity C404 is further formed in the driving block 4, a third motor 405 is arranged in the machine cavity C404, and an output shaft of the third motor 405 penetrates through the inner wall of the machine cavity C404, extends into the gear cavity 401 and is coaxially and fixedly connected with the transmission gear 402.

In the technical scheme, the sliding belt 42 is used for transmission, so that the movement of the scraping and moving block 3 is realized.

The application technical scheme provides a use method of a slag removal machine capable of automatically cleaning water conservancy pipeline slag, which comprises the following steps:

putting the slag removing rod 1 into the pipeline to be cleaned;

starting the first motor 102 to drive the anti-blocking head 103 to rotate so as to break stubborn dregs, wherein the dregs can be conveyed to the rear side of the anti-blocking head 103 along the dreg guide groove 1001 and enter the inner barrel 11 through the inlet 12;

meanwhile, the third motor 405 is started to drive the transmission gear 402 to rotate, so as to drive the sliding belt 42 to rotate, and under the action of the tooth blocks a43 and B, the slag cleaning shaft 21 moves along the limiting groove B44, at this time, the scraping block 3 on the slag cleaning shaft 21 further grinds the inner wall of the pipeline, and the inner part of the slag inner barrel 11 is fed through the inlet 12;

meanwhile, the second motor 2002 is started to drive the conveying auger 201 to rotate, and the residue soil in the inner barrel 11 is conveyed to the outside of the residue removing rod 1.

3. Advantageous effects

One or more technical solutions provided by the present application have at least the following technical effects or advantages:

in the application, when the inner wall of the water conservancy pipeline is effectively scraped, residues can be cleaned out of the pipeline in time, so that subsequent work can be carried out smoothly, and the cleaning efficiency and effect are improved; and the scraping and conveying are synchronous, so that the continuous operation of slag removal is realized.

Drawings

FIG. 1 is a schematic overall structure diagram of a slag remover capable of automatically cleaning water conservancy pipeline slag soil, which is disclosed by the preferred embodiment of the application;

FIG. 2 is a cross-sectional view of the whole structure of the slag remover capable of self-cleaning the slag in the water conservancy pipeline, which is disclosed by the preferred embodiment of the application;

FIG. 3 is a partial structural schematic view of a slag conveying mechanism of a slag removing machine capable of automatically removing water conservancy pipeline slag disclosed by the preferred embodiment of the application;

FIG. 4 is an expanded view of an inner cylinder structure of a slag remover capable of automatically cleaning water conservancy pipeline slag disclosed by the preferred embodiment of the application;

fig. 5 is a schematic structural view of a limiting groove B of a slag remover capable of automatically cleaning water conservancy pipeline slag disclosed by the preferred embodiment of the application;

fig. 6 is an exploded view of a mobile driving structure of a slag remover capable of automatically cleaning water conservancy pipeline slag disclosed by the preferred embodiment of the application.

The reference numbers in the figures illustrate:

1. removing slag rods; 2. a slag conveying mechanism; 3. scraping the moving block; 4. a drive block;

11. an inner barrel; 12. an inlet;

101. a machine cavity A; 102. a first motor; 103. preventing choke plug;

1001. a slag guide groove; 1002. a limiting groove A; 1003. a guide rail;

21. removing slag;

201. conveying the auger;

2001. a machine cavity B; 2002. a second motor;

41. a slideway; 42. a sliding belt; 43. a tooth block A; 44. a limiting groove B;

401. a gear cavity; 402. a transmission gear; 403. a tooth block C; 404. a machine cavity C; 405. a third motor.

Detailed Description

In order to make the implementation objects, technical solutions and advantages of the present invention clearer, the technical solutions in the embodiments of the present invention will be described in more detail below with reference to the accompanying drawings in the embodiments of the present invention. In the drawings, the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The described embodiments are only some, but not all embodiments of the invention.

All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The embodiments and the directional terms described below with reference to the drawings are exemplary and intended to be used in the explanation of the invention, and should not be construed as limiting the invention.

In a wide embodiment of the invention, the slag removing machine capable of automatically removing the water conservancy pipeline slag soil comprises a slag removing rod 1 and a slag conveying mechanism 2, and is characterized in that the slag removing rod 1 is arranged in a hollow structure, and an inner cylinder 11 is fixedly arranged in the hollow part of the slag removing rod 1; the slag conveying mechanism 2 comprises a plurality of slag removing shafts 21, and the plurality of slag removing shafts 21 are arranged around the inner cylinder 11 and distributed at equal intervals in a ring shape; the side surfaces of the slag removing shaft 21 are uniformly and fixedly connected with a plurality of scraping blocks 3 arranged in an arc-shaped structure, and when the slag removing shaft 21 drives the scraping blocks 3 to move the inner wall of the pipeline, the residue is synchronously conveyed away.

Preferably, the distal end of the inner cylinder 11 extends to one side of the distal end of the slag removing rod 1 and is fixedly connected with a connecting column, and the side surface of the inner cylinder 11, which is positioned at the outer part of the slag removing rod 1, is provided with a plurality of inlets 12.

Preferably, a machine cavity A101 is formed in the far end of the connecting column, a first motor 102 is fixedly arranged inside the machine cavity A101, and an output shaft of the first motor 102 penetrates through the inner wall of the machine cavity A101 to extend to the outer side of the connecting column and is fixedly provided with an anti-blocking head 103 in a conical structure.

Preferably, a plurality of slag guide grooves 1001 arranged in a spiral structure are formed in the side surface of the choke plug 103; the diameter of the anti-blocking head 103 is larger than that of the inner barrel 11; a limit groove A1002 is formed in the proximal end face of the choke plug 103, and the limit groove A1002 is arranged in an annular structure; the inside of the limiting groove A1002 is provided with a guide rail 1003 in a sliding manner, and the guide rail 1003 is fixedly connected to the far end face of the connecting column.

Preferably, a conveying auger 201 is rotatably arranged inside the inner cylinder 11, and the conveying auger 201 is matched with the inner diameter of the inner cylinder 11; the distal end of the conveying auger 201 extends to the inlet 12.

Preferably, a machine cavity B2001 is formed in the proximal end of the inner cylinder 11, a second motor 2002 is fixedly arranged in the machine cavity B2001, and an output shaft of the second motor 2002 penetrates through the inner wall of the machine cavity B2001, extends into the inner cylinder 11, and is coaxially and fixedly connected with the conveying auger 201.

Preferably, the far end of the slag removing shaft 21 is provided with a driving block 4, the middle part of the driving block 4 is provided with a slideway 41, the outer wall of the slideway 41 is provided with a sliding belt 42 in a sliding manner, and the outer wall of the sliding belt 42 is fixedly provided with a plurality of uniformly distributed tooth blocks A43; the slag removing rod 1 is characterized in that the far end face is provided with a limiting groove B44, a tooth block B is fixedly arranged in the limiting groove B44, and the tooth block A43 is in meshed connection with the tooth block B.

Preferably, the limiting groove B44 is arranged in an 8-shaped structure; the cross-section of the driving block 4 is in a diamond structure, and the size of the driving block 4 is larger than that of the middle intersection of the limiting groove B44.

Preferably, at least one gear cavity 401 is formed inside the driving block 4, a transmission gear 402 is rotatably arranged inside the gear cavity 401, and the transmission gear 402 is meshed and connected with a gear block C403 fixedly arranged inside the sliding belt 42; at least one machine cavity C404 is further formed in the driving block 4, a third motor 405 is arranged in the machine cavity C404, and an output shaft of the third motor 405 penetrates through the inner wall of the machine cavity C404, extends into the gear cavity 401 and is coaxially and fixedly connected with the transmission gear 402.

The invention also aims to provide a use method of the slag cleaning machine capable of automatically cleaning the water conservancy pipeline slag soil, which comprises the following steps:

putting the slag removing rod 1 into the pipeline to be cleaned;

The present invention will be described in further detail below with reference to the accompanying drawings, which illustrate preferred embodiments of the present invention.

Referring to fig. 4, the technical scheme of the application provides a slag removing machine capable of automatically removing water conservancy pipeline slag soil, which comprises an inner cylinder 11, wherein the far end of the inner cylinder 11 extends to one side of the far end of a slag removing rod 1 and is fixedly connected with a connecting column, the far end of the connecting column is provided with a machine cavity A101, a first motor 102 is fixedly arranged in the machine cavity A101, an output shaft of the first motor 102 penetrates through the inner wall of the machine cavity A101 to extend to the outer side of the connecting column and is fixedly provided with an anti-blocking head 103 in a conical structure, and the anti-blocking head 103 can form a drill bit through rotation to crush and convey a blocking object or a larger object;

prevent that end cap 103 outer wall has seted up and lead slag groove 1001, lead slag groove 1001 and have seted up a plurality ofly, and be the helical structure setting, prevent that end cap 103 diameter is greater than inner tube 11 diameter, prevent that the proximal end face of end cap 103 has seted up spacing groove A1002, spacing groove A1002 is annular structure setting, the inside slip of spacing groove A1002 is provided with guide rail 1003, guide rail 1003 fixed connection is on the distal end face of spliced pole, can be carried the residue by the distal end to the proximal end through leading slag groove 1001.

Referring to fig. 3, in the technical scheme of the application, a plurality of inlets 12 are formed in the side surface of the inner cylinder 11, which is located at the outer part of the slag removing rod 1, a plurality of slag removing shafts 21 are wound around the inlets 12, a plurality of scraping moving blocks 3 are uniformly and fixedly connected to the side surfaces of the slag removing shafts 21, and the scraping moving blocks 3 are arranged in an arc-shaped structure.

Referring to fig. 2 and 4, the technical solution of the present application provides a slag remover capable of self-cleaning water conservancy pipeline slag, a conveying auger 201 is rotatably disposed inside an inner cylinder 11, the conveying auger 201 is adapted to an inner diameter of the inner cylinder 11, a distal end of the conveying auger 201 extends to an inlet 12, a machine cavity B2001 is further formed at a proximal end of the inner cylinder 11, a second motor 2002 is fixedly disposed inside the machine cavity B2001, an output shaft of the second motor 2002 penetrates through an inner wall of the machine cavity B2001 and extends into the inner cylinder 11 and is coaxially and fixedly connected with the conveying auger 201, when an inner wall of a pipeline is scraped, residues can be conveyed out as fast as possible, and thus continuous working cleaning can be achieved.

Referring to fig. 5 and 6, in the technical scheme of the application, a driving block 4 is arranged at the far end of a slag removing shaft 21, a slide way 41 is arranged in the middle of the driving block 4, a sliding belt 42 is slidably arranged on the outer wall of the slide way 41, a plurality of tooth blocks a43 are fixedly arranged on the outer wall of the sliding belt 42, the tooth blocks a43 are arranged at equal intervals, a limit groove B44 is arranged on the outer wall of a slag removing rod 1, uniformly distributed tooth blocks B are fixedly arranged in the limit groove B44, the tooth blocks a43 and the tooth blocks B are in meshing connection, and a scraping block 3 on the slag removing shaft 21 can repeatedly move back and forth on the inner wall of a pipeline, so that sundries adhered to the inner wall can be scraped and collected, and the cleaning effect is improved;

the limiting groove B44 is arranged in an 8-shaped structure, the driving block 4 is arranged in a rhombic structure, the size of the driving block 4 is larger than that of the intersection of the middle part of the limiting groove B44, and the cutting block 3 can continuously perform the working.

Referring to fig. 6, the technical scheme of the application provides a slag removal machine capable of automatically cleaning water conservancy pipeline slag, at least one gear cavity 401 is formed in a driving block 4, a transmission gear 402 is rotatably arranged in the gear cavity 401, the transmission gear 402 is meshed with a tooth block C403 fixedly arranged in a sliding belt 42, at least one machine cavity C404 is further formed in the driving block 4, a third motor 405 is arranged in the machine cavity C404, an output shaft of the third motor 405 penetrates through the inner wall of the machine cavity C404, extends into the gear cavity 401 and is coaxially and fixedly connected with the transmission gear 402, and the sliding belt 42 is used for transmission, so that the movement of the scraping block 3 is realized.

The working principle is as follows: when the slag removing machine is needed, firstly, the slag removing rod 1 is placed into the pipeline, at the moment, the controller drives the first motor 102 to rotate, the anti-blocking head 103 is driven to rotate, the anti-blocking head 103 breaks stubborn slag, and at the moment, the slag can be conveyed to the rear side of the anti-blocking head 103 along the slag guide groove 1001 and enters the inner barrel 11 through the inlet 12; meanwhile, the second motor 2002 is driven to drive the conveying auger 201 to rotate, and the residue soil entering the inner barrel 11 through the inlet 12 is conveyed to the outside of the residue removing rod 1;

meanwhile, the third motor 405 is driven to rotate, the transmission gear 402 is driven to rotate, at this time, the transmission gear 402 is meshed with a tooth block C403 to drive the sliding belt 42 to transmit, at this time, a tooth block a43 on the outer wall of the sliding belt 42 is meshed with a tooth block B in a limiting groove B44 formed in the slag cleaning rod 1, so that the slag cleaning shaft 21 moves along the limiting groove B44, at this time, the scraping block 3 on the slag cleaning shaft 21 further moves on the inner wall of the pipeline, and the slag soil enters the inlet 12 to be conveyed through the conveying auger 201.

Finally, it should be pointed out that: the above examples are only for illustrating the technical solutions of the present invention, and are not limited thereto. Although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. A slag remover capable of automatically cleaning water conservancy pipeline slag soil comprises a slag removing rod and a slag conveying mechanism, and is characterized in that the slag removing rod is arranged in a hollow structure, and an inner cylinder is fixedly arranged in the hollow part of the slag removing rod; the slag conveying mechanism comprises a plurality of slag removing shafts which are arranged around the inner cylinder and distributed at equal intervals in a ring shape; and the side surfaces of the slag removing shaft are uniformly and fixedly connected with a plurality of cutting moving blocks arranged in an arc-shaped structure, and when the slag removing shaft drives the cutting moving blocks to move the inner wall of the pipeline, the residues can be synchronously conveyed out.

2. The slag remover capable of automatically removing dregs in a water conservancy pipeline according to claim 1, wherein the distal end of the inner cylinder extends to one side of the distal end of the slag removing rod and is fixedly connected with a connecting column, and a plurality of inlets are formed in the side surface of the inner cylinder, which is positioned at the outer part of the slag removing rod.

3. The slag removing machine capable of automatically removing water conservancy pipeline slag soil according to claim 2, wherein a machine cavity A is formed in the far end of the connecting column, a first motor is fixedly arranged inside the machine cavity A, and an output shaft of the first motor penetrates through the inner wall of the machine cavity A, extends to the outer side of the connecting column and is fixedly provided with a plug which is arranged in a conical structure.

4. The slag remover capable of automatically removing the slag soil of the water conservancy pipeline according to claim 3, wherein a plurality of slag guide grooves which are arranged in a spiral structure are formed in the side surface of the anti-blocking head; the diameter of the anti-blocking head is larger than that of the inner barrel; a limit groove A is formed in the near-end surface of the anti-blocking head, and the limit groove A is arranged in an annular structure; the limiting groove A is internally provided with a guide rail in a sliding manner, and the guide rail is fixedly connected to the far end face of the connecting column.

5. The slag removing machine capable of automatically removing the slag soil of the water conservancy pipeline according to claim 2, wherein a conveying auger is rotatably arranged inside the inner cylinder, and the conveying auger is matched with the inner diameter of the inner cylinder in size; the far end of the conveying auger extends to the inlet.

6. The slag removing machine capable of automatically removing water conservancy pipeline slag soil according to claim 5, wherein a machine cavity B is formed in the near end of the inner cylinder, a second motor is fixedly arranged in the machine cavity B, and an output shaft of the second motor penetrates through the inner wall of the machine cavity B, extends into the inner cylinder and is coaxially and fixedly connected with the conveying auger.

7. The slag removing machine capable of automatically removing the slag soil of the water conservancy pipeline according to claim 1, wherein a driving block is arranged at the far end of the slag removing shaft, a slide way is arranged in the middle of the driving block, a sliding belt is arranged on the outer wall of the slide way in a sliding manner, and a plurality of uniformly distributed tooth blocks A are fixedly arranged on the outer wall of the sliding belt; the slag removing rod is characterized in that a limiting groove B is formed in the far end face of the slag removing rod, a tooth block B is fixedly arranged in the limiting groove B, and the tooth block A is meshed with the tooth block B.

8. The slag remover capable of automatically removing slag soil of the water conservancy pipeline according to claim 7, wherein the limiting groove B is arranged in a shape like a Chinese character 'ji'; the cross-section of the driving block is of a diamond structure, and the size of the driving block is larger than that of the middle intersection of the limiting groove B.

9. The slag removing machine capable of automatically removing the slag soil of the water conservancy pipeline according to claim 7, wherein at least one gear cavity is formed in the driving block, a transmission gear is rotatably arranged in the gear cavity, and the transmission gear is meshed with a gear block C fixedly arranged in the sliding belt; at least one machine cavity C is further formed in the driving block, a third motor is arranged in the machine cavity C, and an output shaft of the third motor penetrates through the inner wall of the machine cavity C, extends into the gear cavity and is coaxially and fixedly connected with the transmission gear.

10. Use of a slag cleaning machine according to any one of claims 1-9 for self-cleaning water conservancy pipeline slag, characterized in that it comprises the following steps:

putting the slag removing rod into the pipeline to be cleaned;

starting a first motor to drive the anti-blocking head to rotate so as to break stubborn muck, wherein the muck can be conveyed to the rear side of the anti-blocking head along the slag guide groove and enters the inner cylinder through the inlet;

meanwhile, a third motor is started to drive a transmission gear to rotate so as to drive a sliding belt to rotate, the slag cleaning shaft moves along a limiting groove B under the action of a tooth block A and a tooth block B, and a cutting block on the slag cleaning shaft can further move the inner wall of the pipeline on the basis of working at the inlet so as to drive the inner part of the inner slag barrel;

meanwhile, the second motor is started to drive the conveying auger to rotate, and the residue soil of the inner barrel is conveyed to the outside of the residue removing rod.