CN116874004B - Slag drag bucket structure and movable rail type grid dirt remover with same - Google Patents

Abstract

The invention discloses a slag scooping scraper structure and a movable rail type grid dirt remover comprising the same, which comprises a U-shaped connecting plate, wherein one side of the U-shaped connecting plate is fixedly connected with a plurality of groups of slag scooping scraper teeth, the plurality of groups of slag scooping scraper teeth are sleeved in a group of push plates, the push plates are movably connected with the U-shaped connecting plate, telescopic scraper teeth are movably connected in the slag scooping scraper teeth, a plurality of groups of clamping holes are formed in the upper end of the connecting plate, and liquid discharge holes are formed in the slag scooping scraper teeth; along with the continuous upward movement of U type connecting plate, the pollutant can be piled up and drag for sediment rake teeth upside in a plurality of groups, along with the pollutant is dragged for more and more, under the elasticity effect of a plurality of groups of connecting springs, the connecting plate can drive a plurality of flexible rake teeth of group and stretch out from dragging for sediment rake teeth in, through the flexible rake teeth that stretch out plus the length of dragging for sediment rake teeth for U type connecting plate can have more pollutant to be dragged for from in the sewage when rising, realizes once only dragging for a large amount of pollutants that are blocked by the grid.

Description

Slag drag bucket structure and movable rail type grid dirt remover with same

Technical Field

The invention relates to the technical field of grid dirt removers, in particular to a slag dragging scraper bucket structure and a movable rail type grid dirt remover with the same.

Background

The utility model discloses a chinese patent of publication No. CN217418223U, it discloses an automatic angle regulation's movable rail formula grid scrubbing machine, including the support under water, the support upper end is installed on the support under water, drive mechanism is installed to the support upper end under water, threaded rod surface transmission is connected with drags the sediment harrow, the support inner wall is equipped with the slide rail under water, drag for sediment harrow and slide rail sliding connection, drag for sediment harrow up-and-down reciprocating motion through drive mechanism control, drag for sediment harrow upwards promotes the pollutant in the aquatic, the sediment board is promoted the pollutant for the pollutant is discharged from the sediment mouth.

However, the above scheme has the following disadvantages: according to the device, pollutants in water are fished through the drag-out rake, the electric push rod stretches to drive the drag-out plate to rotate, so that the pollutants on the drag-out rake are pushed into the slag discharging port by the drag-out plate, but the conventional drag-out rake cannot control the tooth length of the rake according to the quantity of the sundries, so that when the grid intercepts a large quantity of pollutants at one time, the length of the rake teeth is limited, the pollutants are more and more along with the continuous upward direction of the drag-out rake, and when the pollutants accumulated on the rake are more, a part of pollutants can slide into the water surface again from the drag-out rake, and cannot be fished out all the pollutants intercepted at the grid position at one time.

Disclosure of Invention

The invention aims to provide a slag scooping scraper structure and a movable rail type grid dirt remover with the same, so as to solve the problems in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the utility model provides a drag for sediment rake structure, includes U type connecting plate, U type connecting plate one side fixedly connected with a plurality of groups drag for sediment rake teeth, a plurality of groups drag for sediment rake teeth all cup joints in a set of push pedal, push pedal and U type connecting plate swing joint, drag for sediment rake teeth internal swing joint has flexible rake teeth, flexible rake teeth one end stretches into to connect the intracavity to with connecting plate fixed connection, the connecting plate sliding connection is in the connection intracavity, the connection intracavity is seted up in U type connecting plate, a plurality of groups joint holes have been seted up in the connecting plate upper end, joint has spacing rack bar in the joint hole, spacing rack bar swing joint is in U type connecting plate, spacing rack bar lower extreme is the arc setting;

one side of the limiting toothed bar is meshed with a gear, the gear is movably connected in the U-shaped connecting plate, one side of the gear, which is far away from the limiting toothed bar, is meshed with the connecting toothed bar, the connecting toothed bar is arranged in a yielding cavity, the yielding cavity is formed in the U-shaped connecting plate, one side of the connecting toothed bar, which is far away from the gear, is fixedly connected with a lifting rod, the lifting rod is slidingly connected in the yielding cavity, one end of the lifting rod, which is far away from the connecting toothed bar, extends out of the U-shaped connecting plate, and the lifting rod is arranged on the upper side of the slag dragging rake teeth;

liquid guide cavities are formed in the periphery of the slag dragging rake teeth and are communicated with the guide cavities, the liquid guide cavities are communicated with the external environment through a plurality of groups of liquid discharge holes, the liquid discharge holes are formed in the slag dragging rake teeth, the guide cavities are formed in U-shaped connecting plates, and a water storage cavity is formed in one side of each U-shaped connecting plate, far away from the slag dragging rake teeth

Preferably, a limit cavity is formed in the lower end of the lifting rod, a T-shaped blocking rod is connected in the limit cavity in a sliding mode, the lower end of the T-shaped blocking rod extends out of the limit cavity and is in contact with the yielding cavity, two groups of limit springs are fixedly connected to the upper end of the T-shaped blocking rod, one end of the limit spring, far away from the T-shaped blocking rod, is fixedly connected with the limit cavity, a baffle is fixedly connected to the upper end of the lifting rod, the baffle is connected in a sliding mode in a sliding groove in a U-shaped connecting plate in a sliding mode, and the sliding groove is communicated with the yielding cavity.

Preferably, guide chamber one end is linked together with micropump output, micropump fixed mounting is in U type connecting plate, micropump input stretches into to the water storage intracavity, the inlet opening has been seted up in the U type connecting plate one end, the inlet opening is linked together with the water storage chamber, swing joint has the fly leaf in the inlet opening, fly leaf one end and L type connecting rod fixed connection, L type connecting rod sliding connection is in the guide way, the guide way is seted up in the U type connecting plate, L type connecting rod is kept away from fly leaf one end and is stretched into to the connecting intracavity to with connecting plate fixed connection.

Preferably, one side of the connecting plate, which is far away from the slag dragging rake teeth, is fixedly connected with a plurality of groups of connecting springs, one end of the connecting springs, which is far away from the connecting plate, is fixedly connected with a connecting cavity, and one side of the connecting cavity, which is close to the connecting springs, is internally fixedly connected with a plurality of groups of electromagnets.

Preferably, the T-shaped sliding blocks are fixedly connected to two ends of the push plate and slidably connected to the T-shaped sliding grooves, the T-shaped sliding grooves are formed in the U-shaped connecting plate, screw rods are screwed to the T-shaped sliding blocks, the screw rods are movably connected to the T-shaped sliding grooves, one ends of the screw rods are fixedly connected with the output ends of the motors, and the motors are fixedly installed in the U-shaped connecting plate.

Preferably, the lifter upper end fixedly connected with T type connecting rod, T type connecting rod sliding connection is in the sliding connection intracavity, the sliding connection intracavity is seted up in U type connecting plate, supporting spring has been cup jointed in the T type connecting rod outside, supporting spring one end and sliding connection intracavity fixed connection, the other end and T type connecting rod fixed connection.

In addition, in order to achieve the purpose, the invention also provides a movable rail type grid dirt remover which comprises the slag scooping scraper structure.

Compared with the prior art, the invention has the beneficial effects that: when the pollutant of grid position department interception is more, along with the continuous upward movement of U type connecting plate, the pollutant can be piled up and drag for sediment rake teeth upside in a plurality of groups, along with the pollutant is dragged for more and more, three sets of lifter can be pressed this downwardly movement by the pollutant, through the downwardly movement of lifter, make the connecting tooth pole remove and drive the gear and rotate, make the lower extreme of spacing tooth pole break away from the joint downthehole through the rotation of gear, under the elasticity effect of a plurality of groups of connecting springs, the connecting plate can drive a plurality of flexible rake teeth of group and stretch out from dragging for sediment rake teeth, the length of dragging for sediment rake teeth is added to flexible rake teeth through stretching out, make U type connecting plate can have more pollutant to drag for out from sewage when rising, realize once only dragging for a large amount of pollutants that are blocked by the grid.

Drawings

FIG. 1 is a schematic view of a top-down construction of the present invention;

FIG. 2 is a schematic diagram of a front view structure of the present invention;

FIG. 3 is a schematic view of the structure of the telescopic tine and the slag-dragging tine of the present invention;

FIG. 4 is a schematic side sectional view of the present invention;

FIG. 5 is a schematic diagram of the connection relationship between the connecting toothed bar and the limiting toothed bar;

FIG. 6 is a schematic diagram of a cross-sectional structure of the connection between a liquid guiding cavity and a liquid discharging hole of the invention;

FIG. 7 is a schematic view of the guide lumen of the present invention in a sectional position.

In the figure: 1. a U-shaped connecting plate; 2. a screw rod; 3. a T-shaped chute; 4. a T-shaped slider; 5. a motor; 6. a guide chamber; 7. a connecting plate; 8. a micropump; 9. a water storage chamber; 10. an electromagnet; 11. a connecting spring; 12. a liquid guiding cavity; 13. a movable plate; 14. an L-shaped connecting rod; 15. a connecting cavity; 16. telescoping rake teeth; 17. a guide groove; 18. drag for the dreg rake teeth; 19. a lifting rod; 20. a baffle; 21. a spacing cavity; 22. a limit spring; 23. a relief cavity; 24. a T-shaped blocking rod; 25. connecting a toothed bar; 26. a gear; 27. a limit toothed bar; 28. a water inlet hole; 29. a liquid discharge hole; 30. a push plate; 31. a clamping hole; 32. a chute; 33. a sliding connection cavity; 34. a support spring; 35. t-shaped connecting rod.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-7, the present invention provides a technical solution:

example 1:

the utility model provides a drag for sediment rake structure, including U type connecting plate 1, U type connecting plate 1 one side fixedly connected with a plurality of groups drag for sediment rake 18, a plurality of groups drag for sediment rake 18 all cup joint in a set of push pedal 30, push pedal 30 and U type connecting plate 1 swing joint, flexible rake 16 is connected with in the drag for sediment rake 18, flexible rake 16 one end stretches into in the connecting chamber 15, and fixedly connected with connecting plate 7, connecting plate 7 sliding connection is in connecting chamber 15, connecting chamber 15 opens in U type connecting plate 1, a plurality of groups of joint holes 31 have been seted up in the upper end of connecting plate 7, joint has spacing toothed bar 27 in the joint hole 31, spacing toothed bar 27 swing joint is in U type connecting plate 1, spacing toothed bar 27 lower extreme is the arc setting, when spacing toothed bar 27 lower extreme breaks away from in joint hole 31, at this moment under the elasticity effect of a plurality of groups of connecting springs 11, connecting plate 7 outwards moves and drives a plurality of flexible rake 16 of groups of being connected with it and moves in step, a plurality of groups of flexible rake 16 can increase the area of drag for sediment collection after the flexible rake 16, prevent a large amount of debris from piling up on the rubbish rake 18 because of debris is piled up to the length in the rubbish rake 18, because of debris is piled up in the rubbish has been accumulated on the surface part;

one side of a limiting toothed bar 27 is meshed with a gear 26, the gear 26 is movably connected in the U-shaped connecting plate 1, one side of the gear 26, which is far away from the limiting toothed bar 27, is meshed with a connecting toothed bar 25, the connecting toothed bar 25 is arranged in a yielding cavity 23, the yielding cavity 23 is formed in the U-shaped connecting plate 1, one side of the connecting toothed bar 25, which is far away from the gear 26, is fixedly connected with a lifting rod 19, the lifting rod 19 is slidingly connected in the yielding cavity 23, one end of the lifting rod 19, which is far away from the connecting toothed bar 25, extends out of the U-shaped connecting plate 1, the lifting rod 19 is arranged on the upper side of slag rake teeth 18, when sundries in water are more, three groups of lifting rods 19 arranged on the upper sides of a plurality of slag rake teeth 18 are pressed by sundries to move downwards, the lifting rod 19 moves upwards to drive the connecting toothed bar 25 connected with the lifting rod downwards, and simultaneously a T-shaped connecting rod 35 moves downwards along a sliding connecting cavity 33, so that a supporting spring 34 is compressed, the connecting toothed bar 25 moves downwards to drive the gear 26 to rotate clockwise, and the limiting toothed bar 27 moves upwards, and when the lower end of the limiting toothed bar 27 is separated from a limiting hole 31;

the liquid guide cavity 12 is formed in the periphery of the slag dragging rake teeth 18, the liquid guide cavity 12 is communicated with the guide cavity 6, the liquid guide cavity 12 is communicated with the external environment through a plurality of groups of liquid discharge holes 29, the liquid discharge holes 29 are formed in the slag dragging rake teeth 18, the guide cavity 6 is formed in the U-shaped connecting plate 1, the water storage cavity 9 is formed in one side, far away from the slag dragging rake teeth 18, of the U-shaped connecting plate 1, the micropump 8 is started to pump a water source in the water storage cavity 9 into the guide cavity 6, the water source reenters the liquid guide cavity 12 along the guide cavity 6, the water source entering the liquid guide cavity 12 can be finally discharged from the plurality of groups of liquid discharge holes 29, the surface of the slag dragging rake teeth 18 can be cleaned through the discharged water source, and tiny sundries adhered on the surface of the slag dragging rake teeth 18 are cleaned.

Example 2:

on the basis of embodiment 1, in order to prevent sundry garbage from entering the connecting cavity 23, a limit cavity 21 is formed in the lower end of the lifting rod 19, a T-shaped blocking rod 24 is connected in the limit cavity 21 in a sliding manner, the lower end of the T-shaped blocking rod 24 extends out of the limit cavity 21 and is contacted with the yielding cavity 23, two groups of limit springs 22 are fixedly connected to the upper end of the T-shaped blocking rod 24, one end of the limit spring 22, which is far away from the T-shaped blocking rod 24, is fixedly connected with the limit cavity 21, a baffle 20 is fixedly connected to the upper end of the lifting rod 19, the baffle 20 is connected in a sliding groove 32, the sliding groove 32 is formed in the U-shaped connecting plate 1, the sliding groove 32 is communicated with the yielding cavity 23, when the lifting rod 19 is pressed downwards, the T-shaped blocking rod 24 is pressed into the limit cavity 21, the baffle 20 slides out of the sliding groove 32 at the same time, when the lifting rod 19 moves upwards under the elasticity of the supporting spring 34, the baffle is under the elasticity of the limit spring 22, the T-shaped blocking rod 24 is separated from the yielding cavity 21 and is separated from the yielding cavity 23 and contacted with the yielding cavity 23, and the sundry garbage can be prevented from entering the lifting rod 23 or the yielding cavity 23 when the lifting rod is pressed downwards;

one end of the guide cavity 6 is communicated with the output end of the micropump 8, the micropump 8 is fixedly arranged in the U-shaped connecting plate 1, the input end of the micropump 8 extends into the water storage cavity 9, a water inlet 28 is formed in one end of the U-shaped connecting plate 1, the water inlet 28 is communicated with the water storage cavity 9, a movable plate 13 is movably connected in the water inlet 28, one end of the movable plate 13 is fixedly connected with the L-shaped connecting rod 14, the L-shaped connecting rod 14 is slidingly connected in the guide groove 17, the guide groove 17 is formed in the U-shaped connecting plate 1, one end of the L-shaped connecting rod 14, far from the movable plate 13, extends into the connecting cavity 15 and is fixedly connected with the connecting plate 7, one side, far from the slag rake teeth 18, of the connecting plate 7 is fixedly connected with a plurality of groups of connecting springs 11, one end, far from the connecting plate 7, of the connecting springs 15 is fixedly connected with the connecting cavity 15, and one side, near the connecting springs 11, is fixedly connected with a plurality of groups of electromagnets 10;

the two ends of the push plate 30 are fixedly connected with T-shaped sliding blocks 4, the T-shaped sliding blocks 4 are slidably connected in a T-shaped sliding groove 3, the T-shaped sliding groove 3 is formed in a U-shaped connecting plate 1, a screw rod 2 is connected in the T-shaped sliding groove 4 in a screwed manner, the screw rod 2 is movably connected in the T-shaped sliding groove 3, one end of the screw rod 2 is fixedly connected with the output end of a motor 5, the motor 5 is fixedly arranged in the U-shaped connecting plate 1, two groups of motors 5 are synchronously started and drive the screw rods 2 connected with the output ends of the motors to start rotating, the two groups of screw rods 2 synchronously rotate respectively to drive the corresponding T-shaped sliding blocks 4 to start moving along the T-shaped sliding groove 3, the two groups of T-shaped sliding blocks 4 synchronously move to drive the push plate 30 to start moving outwards, rubber rings are arranged at the contact positions of the push plate 30 and the slag-dragging rake teeth 18, and sundries attached to the surfaces of the slag-dragging rake teeth 18 can be scraped in the moving process;

the lifter 19 upper end fixedly connected with T type connecting rod 35, T type connecting rod 35 sliding connection is in sliding connection chamber 33, sliding connection chamber 33 is seted up in U type connecting plate 1, supporting spring 34 has been cup jointed in the T type connecting rod 35 outside, supporting spring 34 one end and sliding connection chamber 33 fixed connection, the other end and T type connecting rod 35 fixed connection, can drive T type connecting rod 35 synchronous downwardly moving when lifter 19 moves down, supporting spring 34 is compressed simultaneously, after debris rubbish is pushed away from in the U type connecting plate 1, at this moment under supporting spring 34's elasticity effect, lifter plate 19 lifts up again.

In addition, in order to achieve the purpose, the invention also provides a movable rail type grid dirt remover which comprises the slag scooping scraper structure.

When the garbage collection device is used, the U-shaped connecting plate 1 and the grid pollutant remover are installed together, the grid pollutant remover drives the U-shaped connecting plate 1 to move upwards, so that a plurality of groups of the slag-fishing harrow teeth 18 can be separated from the water surface by sundries blocked in the water, when more sundries are contained in the water, three groups of lifting rods 19 arranged on the upper sides of the groups of the slag-fishing harrow teeth 18 can be pressed by sundries to move downwards, the lifting rods 19 move upwards to drive a connecting toothed bar 25 connected with the lifting rods to move, meanwhile, the T-shaped connecting rod 35 can move downwards along a sliding connection cavity 33, so that a supporting spring 34 is compressed, the connecting toothed bar 25 moves downwards to drive a gear 26 to rotate clockwise, the gear 26 rotates clockwise to drive a limiting toothed bar 27 to move upwards, and when the lower ends of the limiting toothed bars 27 are separated from the clamping holes 31, at the moment, under the elastic action of the groups of connecting springs 11, the connecting plate 7 moves outwards rapidly and drives the groups of telescopic harrow teeth 16 connected with the connecting plate to move synchronously, and the areas of the groups of the telescopic harrow teeth 16 can be increased after the groups of telescopic harrow teeth 16 are popped up, so that a large quantity of sundries can be prevented from being accumulated on the water surface due to the fact that the sundries are accumulated on the part of the harrow teeth 18;

meanwhile, the connecting plate 7 drives the L-shaped connecting rod 14 to move along the guide groove 17 in the outward moving process, the L-shaped connecting rod 14 moves to drive the movable plate 13 to move, so that a water source can enter the water storage cavity 9 through the water inlet hole 28 for storage, when a plurality of groups of U-shaped connecting plates 1 carrying sundry garbage move to a sewage discharging port of the grid sewage removing machine, at the moment, garbage can be pulled down from the U-shaped connecting plates 1, at the moment, the micropump 8 starts to pump the water source in the water storage cavity 9 into the guide cavity 6, the water source enters the liquid guide cavity 12 again along the guide cavity 6, the water source entering the liquid guide cavity 12 can be finally discharged from a plurality of groups of liquid discharge holes 29, and the surface of the slag dragging rake teeth 18 can be cleaned through the discharged water source, so that fine sundries adhered to the surface of the slag dragging rake teeth 18 can be cleaned;

meanwhile, after sundry garbage is cleaned down from the plurality of groups of slag-fishing rake teeth 18, the two groups of motors 5 are synchronously started to drive screw rods 2 connected with output ends of the motors to start rotating, the two groups of screw rods 2 synchronously rotate to drive corresponding T-shaped sliding blocks 4 to start moving along the T-shaped sliding grooves 3 respectively, the two groups of T-shaped sliding blocks 4 synchronously move to drive the push plate 30 to start moving outwards, rubber rings are arranged at the contact positions of the push plate 30 and the slag-fishing rake teeth 18, the push plate 30 can scrape the sundry garbage attached to the surfaces of the slag-fishing rake teeth 18 in the moving process, meanwhile, the plurality of groups of electromagnets 10 can synchronously start to generate suction force on the connecting plate 7, so that the connecting plate 7 moves inwards along the connecting cavity 15 and drives the plurality of telescopic rake teeth 16, the telescopic rake teeth 16 move inwards to be retracted into the slag-fishing rake teeth 18, meanwhile, the limiting tooth bars 27 are clamped into the clamping holes 31 again due to the arc-shaped arrangement at the lower ends of the limiting tooth bars 27, and the movable plate 13 can block the water inlet holes 28 again.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a drag for sediment rake fill structure, includes U type connecting plate, and a plurality of groups of drag for sediment rake teeth of U type connecting plate one side fixedly connected with, a plurality of groups drag for sediment rake teeth all cup joint in a set of push pedal, its characterized in that: the pushing plate is movably connected with the U-shaped connecting plate, a telescopic harrow tooth is movably connected in the slag dragging harrow tooth, one end of the telescopic harrow tooth extends into the connecting cavity and is fixedly connected with the connecting plate, the connecting plate is slidably connected in the connecting cavity, the connecting cavity is arranged in the U-shaped connecting plate, a plurality of groups of clamping holes are formed in the upper end of the connecting plate, a limiting toothed bar is clamped in the clamping holes and movably connected in the U-shaped connecting plate, and the lower end of the limiting toothed bar is in an arc shape;

one side of the limiting toothed bar is meshed with a gear, the gear is movably connected in the U-shaped connecting plate, one side of the gear, which is far away from the limiting toothed bar, is meshed with the connecting toothed bar, the connecting toothed bar is arranged in a yielding cavity, the yielding cavity is formed in the U-shaped connecting plate, one side of the connecting toothed bar, which is far away from the gear, is fixedly connected with a lifting rod, the lifting rod is slidingly connected in the yielding cavity, one end of the lifting rod, which is far away from the connecting toothed bar, extends out of the U-shaped connecting plate, and the lifting rod is arranged on the upper side of the slag dragging rake teeth;

the slag dragging rake teeth are internally provided with liquid guide cavities around, the liquid guide cavities are communicated with the guide cavities, the liquid guide cavities are communicated with the external environment through a plurality of groups of liquid discharge holes, the liquid discharge holes are formed in the slag dragging rake teeth, the guide cavities are formed in the U-shaped connecting plate, and the water storage cavities are formed in one side, away from the slag dragging rake teeth, of the U-shaped connecting plate.

2. The slag scooping rake structure according to claim 1, characterized in that: the lifting device is characterized in that a limiting cavity is formed in the lower end of the lifting rod, a T-shaped blocking rod is connected in the limiting cavity in a sliding mode, the lower end of the T-shaped blocking rod extends out of the limiting cavity and is in contact with the yielding cavity, two groups of limiting springs are fixedly connected to the upper end of the T-shaped blocking rod, one end of the limiting spring, far away from the T-shaped blocking rod, of the limiting spring is fixedly connected with the limiting cavity, a baffle is fixedly connected to the upper end of the lifting rod, the baffle is connected in a sliding groove in a sliding mode, the sliding groove is formed in a U-shaped connecting plate, and the sliding groove is communicated with the yielding cavity.

3. The slag scooping rake structure according to claim 1, characterized in that: the utility model discloses a miniature pump, including guiding chamber, connecting plate, micropump, connecting plate, guiding chamber one end is linked together with micropump output, micropump fixed mounting is in the U type connecting plate, micropump input stretches into to the water storage intracavity, the inlet opening has been seted up in the U type connecting plate one end, the inlet opening is linked together with the water storage chamber, the downthehole swing joint that has the fly leaf of inlet, fly leaf one end and L type connecting rod fixed connection, L type connecting rod sliding connection is in the guide way, the guide way is seted up in the U type connecting plate, L type connecting rod is kept away from fly leaf one end and is stretched into to the connecting intracavity to with connecting plate fixed connection.

4. The slag scooping rake structure according to claim 1, characterized in that: the connecting plate is far away from a plurality of groups of connecting springs of slag drag teeth one side fixedly connected with, connecting spring is far away from connecting plate one end and is connected with the chamber fixed connection, connecting chamber is close to connecting spring one side internal fixation and is connected with a plurality of groups of electro-magnet.

5. The slag scooping rake structure according to claim 1, characterized in that: the utility model discloses a motor, including push pedal, T type slider, motor, screw rod swing joint, motor output, T type slider of equal fixedly connected with in push pedal both ends, T type slider sliding connection is in T type spout, T type spout sets up in U type connecting plate, the spiro union has the screw rod in the T type slider, screw rod swing joint is in T type spout, screw rod one end and motor output fixed connection, motor fixed mounting is in U type connecting plate.

6. The slag scooping rake structure according to claim 1, characterized in that: the lifting rod is characterized in that the upper end of the lifting rod is fixedly connected with a T-shaped connecting rod, the T-shaped connecting rod is slidably connected in a sliding connection cavity, the sliding connection cavity is formed in the U-shaped connecting plate, a supporting spring is sleeved on the outer side of the T-shaped connecting rod, one end of the supporting spring is fixedly connected with the sliding connection cavity, and the other end of the supporting spring is fixedly connected with the T-shaped connecting rod.

7. A movable rail type grid dirt remover which is characterized by comprising the slag scooping scraper structure as claimed in any one of claims 1 to 6.