CN115921465B - Anti-fouling treatment device for resin concrete pump station - Google Patents

Abstract

The invention relates to the technical field of concrete pumps, in particular to an anti-fouling treatment device for a resin concrete pump station. According to the invention, the telescopic rod pushes the dredging push plate, residues in the pump body shell are cleaned, the transverse linkage rod is pushed for the first time before the dredging push plate is cleaned, then the transverse linkage rod pushes the upper dislocation block by means of the lower tilting block, so that the movable plate in the cavity moves upwards, and then the crushing top block protrudes from the surface of the dredging push plate.

Description

Anti-fouling treatment device for resin concrete pump station

Technical Field

The invention relates to the technical field of concrete pumps, in particular to an anti-fouling treatment device for a resin concrete pump station.

Background

The concrete conveying pump, also called concrete pump, consists of pump body and conveying pipe. The machine is a machine for continuously conveying concrete along a pipeline by utilizing pressure, and is mainly applied to house construction, bridge construction and tunnel construction. At present, the concrete pump is mainly divided into a gate valve concrete pump and an S valve concrete pump. The other is a pump truck which is formed by installing a pump body on an automobile chassis and then arranging a telescopic or bent distributing rod. The concrete is continuously conveyed to a pouring site in a pressing way through the pipeline, so that the concrete pouring device has good flexibility. When concrete is pumped, the concrete pump needs to continuously pour the concrete into the concrete pump hopper of the concrete delivery tank truck, and in order to prevent large materials from entering the hopper and ensure the operation safety, a grating structure fence is generally designed on the upper surface of the hopper, and the grating structure fence has the main function of preventing the excessive materials in the concrete mortar from entering the hopper, and is a safety protection device at the same time, so that a certain safety protection effect is achieved. Therefore, the filtered concrete is inside the concrete pump, and large-particle impurities are not present;

because concrete is poured into the concrete pump to be conveyed by the pump, the pump cannot be evacuated when pumping the concrete, so the pump pressure is huge, if the pump is empty, damage can be caused to the pump body, so the concrete pump can have concrete residues in the concrete pump when working to the end, the residual concrete is difficult to clean, and the residual concrete can be solidified when the residual concrete is not cleaned timely, so the thickness of the bottom of the concrete pump is thickened, the solidified concrete is more difficult to clean, and finally the use of the concrete pump can be influenced.

Disclosure of Invention

The invention aims to provide an anti-fouling treatment device for a resin concrete pump station, which aims to solve the problems in the process.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a resin concrete pump station is with processing apparatus who prevents siltation, concrete pump processing subassembly is including pump body shell, but handle bottom plate, side logical groove, desilting push pedal, introduce clamp plate, intake manifold, water hose, bearing catheter, inner chamber groove and intracavity fly leaf, but wherein handle the bottom plate setting in the inside downside of pump body shell, side logical groove runs through and sets up in one side of pump body shell, and wherein the desilting push pedal imbeds in one side of the side of keeping away from the side logical groove of pump body shell, the intake manifold imbeds in one side of desilting push pedal not being in the pump body shell, the water hose is evenly installed on the intake manifold, wherein bearing catheter is fixed in one side of intake manifold not installing the water hose, the middle part at the bottom plate can be handled is seted up to the inner chamber groove, and wherein the intracavity fly leaf sets up in the inside of inner chamber groove, but drive linkage subassembly has been arranged to the downside of handle bottom plate.

Preferably, the shape that the desilting push pedal set up is L shape, and wherein pump body shell arranges fixed connection's cover frame in one side of embedding desilting push pedal, and the cover frame covers the desilting push pedal, the water delivery hose all runs through the cover frame and arranges, and wherein bears the shape that the pipe arranged is T shape, the internally mounted of desilting push pedal sets up the standing groove, and wherein bears the pipe setting in the standing groove.

Preferably, the side through groove is internally provided with a groove inner baffle, wherein the upper side of the groove inner baffle is symmetrically provided with deflection-preventing clamping plates, the deflection-preventing clamping plates are all fixed on the pump body shell, the groove inner baffle is provided with a fixedly connected pulling rope, and one side of the pulling rope connected with the groove inner baffle is positioned between the two deflection-preventing clamping plates, wherein the pulling rope penetrates through the pump body shell.

Preferably, the downside of dredging push pedal is evenly offered and is drawn apart from the spout, wherein draws apart from the inside of spout and has been placed the slider, the assembly movable plate of fixed connection is arranged to the downside of removing the slider, and wherein assembly movable plate one side intermediate position arranges fixed connection's telescopic link, the telescopic link runs through the cover frame and arranges, wherein carries out fixed connection between telescopic link and the cover frame, the distance adjustment slide bar of fixed connection is arranged to one side of dredging push pedal, and wherein the distance adjustment slide bar is kept away from one side of dredging push pedal and is arranged fixed connection's extension ejector pad.

Preferably, one side of the bearing catheter is sleeved with a distance-increasing slide pipe, the distance-increasing slide pipe is embedded in the dredging push plate, the distance-increasing slide pipe is fixedly connected with the movable sliding block, a first inclined spray head is embedded and arranged at the lower side of the distance-increasing slide pipe, an inner water delivery cylinder is arranged at the middle position of the inner part of the distance-increasing slide pipe, and a first spring is arranged at the upper side of the inner water delivery cylinder.

Preferably, the lower side of the inner water delivery cylinder is sleeved with a lifting ring, wherein the lifting ring is fixed on the distance-increasing slide pipe, and a second inclined spray head is placed on the lower side of the inner water delivery cylinder, and is embedded and fixed in the dredging push plate.

Preferably, the middle part of the lower side of the cavity movable plate is provided with a fixedly connected upper misplacement block, wherein the upper side of the cavity movable plate is uniformly provided with a fixedly connected crushing jacking block, the crushing jacking blocks are all arranged through the upper side of the dredging pushing plate, the cavity movable plate is provided with fixedly connected elastic reset sheets, the two sides of the cavity movable plate are symmetrically arranged through guide rods, the guide rods are fixed on a pump body shell, and a direction-changing column is arranged below the cavity movable plate, wherein the direction-changing column is fixed on a treatable bottom plate.

Preferably, the driving linkage assembly comprises a traversing linkage rod, an adjusting chute, a supporting vertical plate, a placing inner rod, a second spring and a downward tilting block, wherein the adjusting chute is arranged on one side of the traversing linkage rod, the supporting vertical plate penetrates through one side of the adjusting chute to be arranged, the placing inner rod is placed in the adjusting chute, the second spring is sleeved on the placing inner rod, and the downward tilting block is fixed on one side of the traversing linkage rod.

Preferably, the traversing linkage rod penetrates through the lower side of the pump body shell, one side of the traversing linkage rod, which is positioned in the pump body shell, is fixedly connected with the other side of the pulling rope, the supporting vertical plate is fixedly connected with the pump body shell, the placing inner rod is fixedly connected with the traversing linkage rod, one side of the traversing linkage rod, which is positioned outside the pump body shell, is provided with a fixedly connected branch rod, one side of the branch rod, which is far away from the traversing linkage rod, is sleeved with a follow-up frame, and a third spring is arranged in the follow-up frame.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, the telescopic rod pushes the dredging push plate, residues in the pump body shell are cleaned, the transverse linkage rod is pushed for the first time before the dredging push plate is cleaned, then the transverse linkage rod pushes the upper dislocation block by means of the lower tilting block, so that the movable plate in the cavity moves upwards, and then the crushing top block protrudes from the surface of the dredging push plate.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic front view of a pump body housing of the present invention in semi-section.

FIG. 3 is a schematic front view of the water inlet manifold of the present invention.

Fig. 4 is a schematic perspective view of a dredging plate according to the present invention.

Fig. 5 is a perspective view of the telescopic rod of the present invention.

FIG. 6 is a schematic perspective view of a movable plate in a cavity of the present invention.

Fig. 7 is a schematic front view of a half-section of the distance-increasing slide tube of the present invention.

Fig. 8 is a schematic perspective view of the present invention in semi-section across a linkage rod.

Fig. 9 is an enlarged schematic view of the invention at a in fig. 2.

Fig. 10 is an enlarged schematic view of the invention at B in fig. 3.

In the figure: 1. a pump body housing; 11. a disposable floor; 12. a side through groove; 1201. a partition plate in the groove; 1202. an anti-deflection clamping plate; 1203. pulling the rope; 13. a dredging push plate; 1301. a pulling distance chute; 1302. moving the slide block; 1303. an assembly moving plate; 1304. a telescopic rod; 1305. a distance-adjusting slide bar; 1306. extending the pushing block; 14. introducing a pressing plate; 15. a water inlet main pipe; 16. a water hose; 17. a carrier catheter; 1701. a distance-increasing slide tube; 1702. a first tilt head; 1703. an internal water supply cylinder; 1704. a first spring; 1705. raising the ring; 1706. a second tilt head; 18. an inner cavity groove; 19. a movable plate in the cavity; 1901. a misplacement block is arranged; 1902. crushing the ejector block; 1903. an elastic reset piece; 1904. a guide bar; 1905. a redirecting column; 2. traversing the linkage rod; 201. a branch rod; 202. a follow-up frame; 203. a third spring; 21. adjusting the chute; 22. a supporting vertical plate; 23. placing an inner rod; 24. a second spring; 25. and (5) a downward warping block.

Detailed Description

Features and exemplary embodiments of various aspects of the invention are described in detail below. In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced without some of these specific details. The following description of the embodiments is merely intended to provide a better understanding of the invention by showing examples of the invention. The present invention is in no way limited to any particular configuration and algorithm set forth below, but rather covers any modification, substitution, and improvement of elements, components, and algorithms without departing from the spirit of the invention. In the drawings and the following description, well-known structures and techniques have not been shown in order to avoid unnecessarily obscuring the present invention.

Referring to fig. 1 to 10, the present invention provides a technical solution: the concrete pump treatment assembly comprises a pump body shell 1, a treatable bottom plate 11, a side through groove 12, a dredging push plate 13, an introducing pressing plate 14, a water inlet header 15, a water delivery hose 16, a bearing conduit 17, an inner cavity groove 18 and an intracavity movable plate 19, wherein the treatable bottom plate 11 is arranged at the lower side of the inside of the pump body shell 1, the side through groove 12 penetrates through one side of the pump body shell 1, the dredging push plate 13 is embedded at one side of the pump body shell 1 far away from the side through groove 12, the introducing pressing plate 14 is arranged below the dredging push plate 13, the water inlet header 15 is embedded at one side of the dredging push plate 13 which is not arranged in the pump body shell 1, the water delivery hose 16 is uniformly arranged on the water inlet header 15, the bearing conduit 17 is fixed at one side of the water delivery hose 16 which is not arranged, the inner cavity groove 18 is arranged at the middle of the treatable bottom plate 11, the intracavity movable plate 19 is arranged at the inner side of the inner cavity groove 18, and a driving linkage assembly is arranged at the lower side of the treatable bottom plate 11. The side of the water hose 16 remote from the water inlet manifold 15 is connected to a water reservoir, and water in the reservoir is supplied to the inside of the water hose 16 by pressurization, and then the water hose 16 supplies water to the inside of the water inlet manifold 15.

The lead-in pressure plate 14 is connected with the pump body housing 1.

The shape that desilting push pedal 13 set up is L shape, and wherein pump body shell 1 arranges fixed connection's cover frame in one side of embedding desilting push pedal 13, and the cover frame covers desilting push pedal 13, and water hose 16 all runs through the cover frame and arranges, and wherein bears the shape that pipe 17 arranged is T shape, and the setting groove is seted up to the inside of desilting push pedal 13, and wherein bears pipe 17 setting in the setting groove.

An in-groove baffle 1201 is arranged in the side through groove 12, wherein the upper sides of the in-groove baffles 1201 are symmetrically provided with deflection-preventing clamping plates 1202, the deflection-preventing clamping plates 1202 are all fixed on the pump body shell 1, a fixedly connected pulling rope 1203 is arranged on the in-groove baffles 1201, one side, connected with the in-groove baffles 1201, of the pulling rope 1203 is positioned between the two deflection-preventing clamping plates 1202, and the pulling rope 1203 penetrates through the pump body shell 1. The two anti-bias clamping plates 1202 can limit the position of the in-groove partition plate 1201 and prevent the in-groove partition plate 1201 from inclining, so that the in-groove partition plate 1201 can move up and down, and the in-groove partition plate 1201 controls the opening and closing of the side through groove 12.

The lower side of dredging push pedal 13 evenly sets up and draws apart from spout 1301, wherein draw apart from the inside of spout 1301 and have placed the removal slider 1302, the assembly movable plate 1303 of fixed connection is arranged to the downside of removal slider 1302, wherein the telescopic link 1304 of fixed connection is arranged to assembly movable plate 1303 one side intermediate position, telescopic link 1304 runs through the cover frame and arranges, wherein carry out fixed connection between telescopic link 1304 and the cover frame, the spacing adjustment slide bar 1305 of fixed connection is arranged to one side of dredging push pedal 13, wherein the spacing adjustment slide bar 1305 is arranged the extension ejector pad 1306 of fixed connection far away from one side of dredging push pedal 13. The distance adjusting slide bar 1305 adopts an elastic telescopic rod, so that the distance adjusting slide bar 1305 can be elastically telescopic.

One side of the bearing conduit 17 is sleeved with a distance increasing slide tube 1701, wherein the distance increasing slide tube 1701 is embedded in the dredging push plate 13, the distance increasing slide tube 1701 is fixedly connected with the movable slide block 1302, a first inclined spray nozzle 1702 is embedded and arranged on the lower side of the distance increasing slide tube 1701, an inner water delivery tube 1703 is arranged in the middle position of the inner part of the distance increasing slide tube 1701, and a first spring 1704 is arranged on the upper side of the inner water delivery tube 1703. A restriction block is placed inside the first spring 1704, and the restriction block is fixed to the distance-increasing slider 1701.

When the dredging push plate 13 is required to clean residual concrete in the pump body shell 1, the telescopic rod 1304 is utilized to push the assembly moving plate 1303, then all the moving sliding blocks 1302 slide in the pull distance sliding groove 1301, the further distance increasing sliding tube 1701 is pushed, then the distance increasing sliding tube 1701 stretches out of the dredging push plate 13, the water delivery hose 16 is further delivered, so that water enters the distance increasing sliding tube 1701 through the bearing conduit 17, then the water is sprayed out of the first inclined spray head 1702, the disposable bottom plate 11 is cleaned in the moving process of the dredging push plate 13, the disposable bottom plate 11 is easy to clean, meanwhile, the telescopic rod 1304 can continuously push the assembly moving plate 1303, then the dredging push plate 13 can push the residues on the disposable bottom plate 11, the dredging push plate 13 can push the residues to one side of the side through groove 12 outside the pump body shell 1, and the residues can be cleaned conveniently.

The lower side of the inner water delivery cylinder 1703 is sleeved with a lifting circular ring 1705, wherein the lifting circular ring 1705 is fixed on the distance-increasing slide tube 1701, the lower side of the inner water delivery cylinder 1703 is provided with a second inclined spray nozzle 1706, and the second inclined spray nozzle 1706 is embedded and fixed in the dredging push plate 13. After the distance-increasing slide 1701 is pushed for the first time, the first tilt head 1702 is exposed back, and the second tilt head 1706 does not correspond to the position of the inner water delivery barrel 1703, because the inner water delivery barrel 1703 is retracted to the inside of the distance-increasing slide 1701 when the distance-increasing slide 1701 is pushed, and then the inner water delivery barrel 1703 and the second tilt head 1706 are covered by the dredging push plate 13, so that water does not emerge from the inside of the inner water delivery barrel 1703.

The middle part of the lower side of the cavity movable plate 19 is provided with a fixedly connected upper dislocation block 1901, wherein the upper side of the cavity movable plate 19 is uniformly provided with a fixedly connected crushing top block 1902, the crushing top blocks 1902 are all arranged through the upper side of the dredging push plate 13, the cavity movable plate 19 is provided with fixedly connected elastic reset pieces 1903, the elastic reset pieces 1903 are positioned between the two crushing top blocks 1902, two sides of the cavity movable plate 19 are symmetrically and penetratingly provided with guide rods 1904, the guide rods 1904 are fixed on the pump body shell 1, the lower side of the cavity movable plate 19 is provided with a redirection column 1905, and the redirection column 1905 is fixed on the disposable bottom plate 11.

The driving linkage assembly comprises a traversing linkage rod 2, an adjusting chute 21, a supporting vertical plate 22, a placing inner rod 23, a second spring 24 and a downward tilting block 25, wherein the adjusting chute 21 is arranged on one side traversing the linkage rod 2, the supporting vertical plate 22 penetrates through one side of the adjusting chute 21, the placing inner rod 23 is placed in the adjusting chute 21, the second spring 24 is sleeved on the placing inner rod 23, and the downward tilting block 25 is fixed on one side traversing the linkage rod 2. An inner rod 23 is disposed through one side of the support riser 22.

The traversing linkage rod 2 is arranged penetrating through the lower side of the pump body shell 1, one side of the traversing linkage rod 2, which is positioned in the pump body shell 1, is fixedly connected with the other side of the pulling rope 1203, the supporting vertical plate 22 is fixedly connected with the pump body shell 1, the inner rod 23 is placed and is fixedly connected with the traversing linkage rod 2, the side of the traversing linkage rod 2, which is positioned outside the pump body shell 1, is provided with the branch rod 201 fixedly connected, one side of the branch rod 201, which is far away from the traversing linkage rod 2, is sleeved with the follow-up frame 202, and the inside of the follow-up frame 202 is provided with the third spring 203. The third spring 203 is located above the branch 201, and a round rod may be disposed in the third spring 203 in a penetrating manner, where the round rod is fixedly connected with the follower 202, and the round rod guides and limits the movement of the follower 202.

When the telescopic rod 1304 pushes the follow-up frame 202 for the first time, the transverse linkage rod 2 pushes the follow-up frame 202 for the first time, then the transverse linkage rod 2 pushes the upper dislocation block 1901 by means of the lower tilting block 25, so that the cavity movable plate 19 moves upwards, and then the crushing jacking block 1902 protrudes from the surface of the dredging push plate 13, so that when the dredging push plate 13 cleans concrete residues, the concrete solidified in the pump body shell 1 can be crushed, the efficiency of residual concrete cleaning is effectively improved, meanwhile, in the moving process of the follow-up frame 202, the guide pressing plate 14 presses the follow-up frame 202 downwards, so that the follow-up frame 202 moves downwards and is staggered with the assembly moving plate 1303, the first pushed work of the transverse linkage rod 2 is completed, the further telescopic rod 1304 pushes the dredging push plate 13, residues in the pump body shell 1 are cleaned, meanwhile, the transverse linkage rod 2 is pushed for the second time by means of the extending the pushing block 1306, the inner side of the rope 1203 is pulled by the transverse linkage rod 2, and the residual concrete is pulled out of the groove 1201, and the residual concrete is discharged from the side groove 1201.

The different technical features presented in the different embodiments may be combined to advantage. Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in view of the drawings, the description, and the claims. In the claims, the term "comprising" does not exclude other means or steps; the indefinite article "a" does not exclude a plurality; the terms "first," "second," and the like, are used for designating a name and not for indicating any particular order. Any reference signs in the claims shall not be construed as limiting the scope. The functions of the various elements presented in the claims may be implemented by means of a single hardware or software module. The presence of certain features in different dependent claims does not imply that these features cannot be combined to advantage.

Claims (6)

1. The utility model provides a resin concrete pump station is with processing apparatus who prevents silting, includes concrete pump processing module, its characterized in that: the concrete pump treatment assembly comprises a pump body shell (1), a treatable bottom plate (11), a side through groove (12), a dredging push plate (13), an introduction pressing plate (14), a water inlet main pipe (15), a water delivery hose (16), a bearing conduit (17), an inner cavity groove (18) and an intracavity movable plate (19), wherein the treatable bottom plate (11) is arranged at the lower side of the inside of the pump body shell (1), the side through groove (12) is penetrated and arranged at one side of the pump body shell (1), the dredging push plate (13) is embedded at one side of the pump body shell (1) far away from the side through groove (12), the introduction pressing plate (14) is arranged below the dredging push plate (13), the water inlet main pipe (15) is embedded at one side of the dredging push plate (13) which is not arranged in the pump body shell (1), the water delivery hose (16) is uniformly arranged on the water inlet main pipe (15), the bearing conduit (17) is fixed at one side of the water delivery hose (16), the inner cavity groove (18) is arranged at one side of the middle part of the treatable bottom plate (11), the inner cavity groove (19) is arranged at one side of the inside of the pump body shell (1), the inner cavity groove (12) is arranged at the side of the inner cavity (19, the inner side of the movable bottom plate (1201 is arranged at the side of the pump assembly, wherein the upper sides of the in-tank partition plates (1201) are symmetrically provided with anti-deflection clamping plates (1202), the anti-deflection clamping plates (1202) are all fixed on a pump body shell (1), a fixedly connected pulling rope (1203) is arranged on the in-tank partition plates (1201), one side, connected with the in-tank partition plates (1201), of the pulling rope (1203) is positioned between the two anti-deflection clamping plates (1202), the pulling rope (1203) penetrates through the pump body shell (1), the driving linkage assembly comprises a traversing linkage rod (2), an adjusting sliding groove (21), a supporting vertical plate (22), an inner rod (23), a second spring (24) and a lower tilting block (25), the adjusting sliding groove (21) is arranged on one side traversing the linkage rod (2), the supporting vertical plate (22) penetrates through one side of the adjusting sliding groove (21), the inner rod (23) is positioned inside the adjusting sliding groove (21), the second spring (24) is sleeved on the inner rod (23), the lower tilting block (25) is fixed on one side of the traversing linkage rod (2), the other side, connected with the lower side (1203) penetrating through the pump body shell (1) fixedly, the other side (1) is positioned on the other side, connected with the lower lifting plate (1), the inner placing rod (23) is fixedly connected with the transverse linkage rod (2), a branch rod (201) which is fixedly connected is arranged on one side of the transverse linkage rod (2) which is positioned outside the pump body shell (1), a follow-up frame (202) is sleeved on one side of the branch rod (201) which is far away from the transverse linkage rod (2), and a third spring (203) is arranged inside the follow-up frame (202).

2. The anti-fouling treatment device for a resin concrete pump station according to claim 1, wherein: the shape that desilting push pedal (13) set up is L shape, and wherein pump body shell (1) arranges fixed connection's cover frame in one side of embedding desilting push pedal (13), and the cover frame covers desilting push pedal (13), water delivery hose (16) all run through the cover frame and arrange, and wherein bear the shape that pipe (17) arranged is T shape, the mounting groove is seted up to the inside of desilting push pedal (13), and wherein bear pipe (17) setting in the mounting groove.

3. The anti-fouling treatment device for a resin concrete pump station according to claim 2, wherein: the dredging device is characterized in that a pull distance sliding groove (1301) is uniformly formed in the lower side of the dredging push plate (13), a movable sliding block (1302) is arranged in the pull distance sliding groove (1301), a fixedly connected assembly movable plate (1303) is arranged on the lower side of the movable sliding block (1302), a fixedly connected telescopic rod (1304) is arranged in the middle of one side of the assembly movable plate (1303), the telescopic rod (1304) penetrates through a covering frame to be arranged, the telescopic rod (1304) is fixedly connected with the covering frame, a fixedly connected distance adjusting sliding rod (1305) is arranged on one side of the dredging push plate (13), and a fixedly connected extending push block (1306) is arranged on one side, far away from the dredging push plate (13), of the distance adjusting sliding rod (1305).

4. A fouling prevention treatment device for a resin concrete pump station according to claim 3, characterized in that: one side of the bearing catheter (17) is sleeved with a distance-increasing slide tube (1701), the distance-increasing slide tube (1701) is embedded in the dredging push plate (13), the distance-increasing slide tube (1701) is fixedly connected with the movable slide block (1302), a first inclined spray head (1702) is embedded and arranged at the lower side of the distance-increasing slide tube (1701), an inner water delivery cylinder (1703) is arranged at the middle position inside the distance-increasing slide tube (1701), and a first spring (1704) is arranged at the upper side of the inner water delivery cylinder (1703).

5. The anti-fouling treatment device for a resin concrete pump station according to claim 4, wherein: the lower side of the inner water delivery barrel (1703) is sleeved with a lifting circular ring (1705), wherein the lifting circular ring (1705) is fixed on the distance-increasing slide tube (1701), a second inclined spray head (1706) is placed on the lower side of the inner water delivery barrel (1703), and the second inclined spray head (1706) is embedded and fixed in the dredging push plate (13).

6. The anti-fouling treatment device for a resin concrete pump station according to claim 5, wherein: the utility model provides a pump body, including cavity fly leaf (19) and flexible reset piece, the downside middle part of cavity fly leaf (19) sets up fixed connection's last dislocation piece (1901), wherein cavity fly leaf (19) upside evenly sets up fixed connection's crushing kicking block (1902), smash kicking block (1902) and all run through the upside of desilting push pedal (13) and arrange, wherein arrange fixed connection's elasticity reset piece (1903) on cavity fly leaf (19), the both sides symmetry of cavity fly leaf (19) run through and arrange guide bar (1904), wherein guide bar (1904) are fixed on pump body shell (1), redirecting post (1905) are arranged to the below of cavity fly leaf (19), wherein redirecting post (1905) are fixed on disposable bottom plate (11).

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