CN108193726B - Multifunctional silt remover for hydraulic engineering - Google Patents

Abstract

The invention discloses a novel multifunctional dredging machine for hydraulic engineering, which structurally comprises: the silt remover comprises a supporting bracket, a mounting column, a silt removing transmission device, air valves, a water inlet pipe, a rotary bearing seat, a handle rod frame and a cross beam frame, wherein the two air valves are parallel to each other and are welded into an integrated structure through the supporting bracket perpendicular to the inner side surface, the cross beam frame is fixedly arranged on the upper surface of the supporting bracket in a welding mode, the rotary bearing seat is vertically connected with the rear side of the upper surface of the air valve and is of an integrated structure with the upper surface of the air valve, and the cross beam frame is embedded into the inner side surface of the rotary bearing seat and is connected with the rotary bearing seat in a clearance fit mode.

Description

Multifunctional silt remover for hydraulic engineering

Technical Field

The invention discloses a multifunctional silt remover for hydraulic engineering, and belongs to the field of silt removers.

Background

Hydraulic engineering is a general term for various engineering constructions built for controlling, utilizing and protecting water resources and environments on the earth surface and underground.

The engineering is built for eliminating water damage and developing and utilizing water resource. The service objects are divided into flood control engineering, farmland hydraulic engineering, hydroelectric power engineering, channel and harbor engineering, water supply and drainage engineering, environmental hydraulic engineering, coastal reclamation engineering and the like. The hydraulic engineering which can serve multiple targets such as flood control, water supply, irrigation, power generation and the like at the same time is called comprehensive utilization hydraulic engineering. Hydraulic engineering needs to build various types of hydraulic buildings such as dams, dikes, spillways, water gates, water inlets, channels, transition troughs, rafts, fishways and the like so as to achieve the aims. Compared with other projects, the hydraulic engineering has the following characteristics: the influence is wide. The hydraulic engineering planning is a component of basin planning or regional hydraulic planning, and the construction of a hydraulic engineering has great influence on the environment of the surrounding region, so that the construction of the hydraulic engineering is beneficial to removing harm and is also disadvantageous to submerging, immigration and the like. Therefore, a hydraulic engineering plan is formulated, which needs to be designed from the whole situation of a drainage basin or a region, and the overall consideration is carried out so as to reduce or avoid adverse effects and obtain the best economic, social and environmental effects. Secondly, the hydraulic engineering is large in scale, large in investment, complex in technology and long in construction period.

A silt remover for removing the bottom sediment in the culture water area.

However, the silt remover in the prior art cannot enable the device inside the equipment to be capable of smashing too large silt when the silt remover works, cannot enable the silt to be softened and prevent internal blockage by adding water, cannot enable the device to be capable of cleaning independently, and cannot enable the device to be more perfect.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a multifunctional dredging machine for hydraulic engineering, and aims to solve the problems that when the dredging machine works, a device in the equipment cannot stir up overlarge sludge, water cannot be added to soften the sludge so as to prevent internal blockage, the device cannot be cleaned independently, and the device cannot be more perfect.

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a multi-functional for hydraulic engineering silt remover, its structure includes: a supporting bracket, a mounting column, a desilting transmission device, an air valve, a first water inlet pipe, a rotating bearing seat, a handle bar frame and a cross beam frame, the two air valves are parallel to each other and welded into an integrated structure through a support bracket perpendicular to the inner side surface, the rotary bearing seat is fixedly arranged on the upper surface of the supporting bracket in a welding way, the rotary bearing seat is vertically connected with the rear side of the upper surface of the air valve and is of an integrated structure with the air valve, the beam frame is embedded into the inner side surface of the rotary bearing seat and is connected with the rotary bearing seat by clearance fit, the mounting column is positioned above the cross beam frame and is movably connected with the cross beam frame, the dredging transmission device is positioned in the vertical direction of the mounting column and extends and is welded with the mounting column to form an integrated structure, the first water inlet pipe is arranged above the dredging transmission device and is communicated with the dredging transmission device, and the handle rod frame is positioned on the lower surface of the cross beam frame and is integrated with the cross beam frame;

the dredging transmission device is provided with a negative pressure pump device, a power stirring device, a pressurization adjusting device, a water absorption transmission device, an extrusion discharging device and a mixing rotating device;

mix rotating device and locate the central authorities of equipment lower surface and be in the same place rather than fixed connection simultaneously, power agitating unit connects perpendicularly in the left side of mixing rotating device lower surface and link up with it mutually, negative pressure pump device imbeds power agitating unit's inside perpendicularly and rather than linking together through the welded mode, pressurization adjusting device is located the left side end of mixing rotating device upper surface and link up the inside of mixing rotating device simultaneously, extrusion discharge apparatus locates the upper right side of mixing rotating device and connects into integrated structure through the pipeline simultaneously, it locates both mutually perpendicular of extrusion discharge apparatus's upper surface to absorb water transmission device.

Further, the negative pressure pump device is provided with a connector, a fixed base, a mud inlet pipe, a pipe body, a power supply box, a negative pressure fan and a mud outlet pipe.

Further, negative-pressure air fan is located unable adjustment base's upper surface and both constitute the integral structure, negative-pressure air fan's right side surface is located to the power supply box and is connected rather than the electricity simultaneously, negative-pressure air fan is located the inside of the perpendicular embedding body of front surface of body simultaneously and adopts clearance fit rather than, it fixes into the integral structure through the welded mode simultaneously to advance the lower extreme that mud pipe is located the body inside, it is parallel to each other and body integral structure with advancing mud pipe to go out the mud pipe, the rear side surface of mud pipe is located and the parcel is gone out the mud pipe to the adapter.

Further, the power stirring device is provided with a central shaft, a propeller, a crushing cabin, a cutter, a transmission shaft, a belt pulley shaft, a belt, a driving motor, a driving shaft and a meshing gear, the central shaft is vertically arranged at the upper end of the bottom surface in the crushing cabin and is movably connected with the crushing cabin, the cutter and the left and right side surfaces of the central shaft form an integrated structure in a welding mode, the outer end of the lower surface of the central shaft is wrapped by the propeller and is integrated with the propeller, the transmission shaft extends upwards in the vertical direction of the central shaft and is movably connected together, the belt pulley shaft is vertical to the upper surface of the transmission shaft and is meshed together, the belt wheel shaft is matched into an integrated structure through a belt positioned on the outer side surface of the belt wheel shaft, the driving shaft is vertically embedded into the inner side surface of the driving motor and is in clearance fit with the driving motor, and the meshing gear is vertically connected to the right side surface of the driving shaft.

Furthermore, the pressurization adjusting device is provided with a pressurization cabin, a steel rope belt, a rubber pad, a fixed plug, a shell, a conveying pipe, a threaded seat, a threaded rod, a rotating handle, a jacking rod, a transfer gear, a rotating disc, a bevel gear and a connecting rod frame, wherein the bevel gear and the transfer gear are parallel to each other and are meshed with the transfer gear to form an integrated structure, the transfer gear and the rotating disc are of a concentric circle structure and form an integrated structure through a shaft, the connecting rod frame is positioned on the upper surface of the transfer gear and the upper surface of the bevel gear to form an integrated structure, the jacking rod penetrates through the pressurization cabin and is mutually connected with the rubber pad positioned in the pressurization cabin, the rubber pad is in clearance fit with the inner side surface of the pressurization cabin, the steel rope belt wraps the outer side surface of the rotating disc, the conveying pipe is embedded into the pressurization cabin and is fixedly connected with the pressurization cabin, the conveying pipe is, the fixed plug wraps the lower surface of the threaded rod and is movably matched with the threaded rod, the threaded rod penetrates through the upper surface of the threaded seat and is in threaded connection with the threaded seat, and the rotating handle is perpendicular to the upper surface of the threaded rod and is welded with the threaded rod to form an integrated structure.

Furthermore, the water absorption transmission device is provided with an absorption pump, a water collector, a U-shaped pipe, a pull rope, a rotating frame, a matching rod, a limiting frame, a sliding block, a matching rod frame, a conveying wheel, a conveying rope, a rotation matching wheel and an auxiliary motor, wherein the absorption pump is positioned on the right side surface of the U-shaped pipe and communicated with the U-shaped pipe, the U-shaped pipe is arranged on the upper surface of the water collector and movably connected with the water collector, the pull rope is positioned on the upper surface of the absorption pump and welded with the absorption pump to form an integrated structure, the pull rope is arranged on the lower surface of the rotating frame, the rotating frame is arranged on the upper surface of the sliding block through the matching rod positioned on the rear side surface of the rotating frame and in clearance fit with the sliding block, the sliding block is embedded in the inner side surface of the limiting frame and in clearance fit with the sliding block, the matching rod frame is positioned below the matching rod and fixedly connected, the conveying wheel and the rotating matching wheel form an integrated structure through a conveying rope, and the auxiliary motor is perpendicular to the lower surface of the rotating matching wheel and is meshed with the rotating matching wheel at the same time.

Furthermore, the extrusion unloading device is provided with an extrusion chamber, a sealing frame, a shaft seat, an ejector rod, an unloading pipe, a plate body, a movable rod frame, an ejection connecting rod, a sliding shaft frame, a portal frame, a rolling slide seat, an extrusion block and a filter layer, wherein the ejection connecting rod is positioned on the right side surface of the movable rod frame and forms an integrated structure by penetrating through the sliding shaft frame, the sliding shaft frame is fixedly arranged in the center of the right side surface of the portal frame, the rolling slide seat is positioned on the left side surface of the portal frame and is movably connected with the portal frame, the movable rod frame is matched with the rolling slide seat in a clearance fit mode and is movably connected with the extrusion block in front, the filter layer is arranged on the left side end surface of the extrusion chamber, the plate body is positioned on the lower surface of the extrusion block and is movably arranged on the bottom side surface of the extrusion chamber through the shaft seat positioned in the center of the, the sealing frame is fixedly connected with the ejector rod positioned on the right end face of the sealing frame, and the discharge pipe is vertically embedded into the lower surface of the extrusion cabin and is communicated with the extrusion cabin.

Further, mix rotating device and be equipped with and mix cabin, inlet pipe, planet wheel, discharging pipe, sealed carousel, sun gear, mounting panel, second inlet tube, the perpendicular left side of embedding mixing cabin upper surface of second inlet tube, the inlet pipe is parallel to each other and the perpendicular central authorities that imbed mixing cabin lower surface simultaneously with the discharging pipe, the inside central authorities of mixing cabin are located to the sun gear, the mounting panel is the disc of equidimension and wraps up the outside of sun gear with the sun gear, the planet wheel is located sun gear inboard and adopts the mode swing joint of meshing together on the surface, sealed carousel is wrapping up the outside of sun gear and rather than welding into integral structure.

Advantageous effects

The invention relates to a multifunctional silt remover for hydraulic engineering, which is characterized in that equipment is electrified, an air valve is placed on a river channel, then a handle rod frame is used for pushing, a negative pressure fan is electrified to enable external silt to enter the interior of a pipe body through a silt inlet pipe and enter the interior of a crushing cabin through a silt outlet pipe through the conveying of the pipe body, a driving motor is electrified to rotate and enables a driving shaft to rotate under the action of electromagnetic induction and drive a belt wheel frame on the driving shaft to rotate, a central shaft below is rotated through the rotation of a belt to enable a cutter and a propeller below to rotate to stir up massive dirt in the silt and enter the interior of a mixing cabin below through a feeding pipe, a bevel gear in front is rotated and drives a connecting rod frame to rotate through the rotation of a meshing gear, and an inner rubber pad is downward through the driving of the connecting rod frame through the meshing gear, and the planet wheel below is driven by the rotating disc and the conveying rope on the outer side to rotate on the sun wheel and complete feeding in the rotating process, at the moment, sludge is conveyed out through the discharge pipe under the rotating drive, and is conveyed into the extrusion chamber, meanwhile, the auxiliary motor rotates to enable the rotation matching wheel to rotate, enable the ejection connecting rod on the outer side to rotate and push the ejection connecting rod and stop after the ejection connecting rod pushes the portal frame forwards against the outer side surface of the rolling sliding seat of the column in the pushing process, then, after the continuous pushing, the movable rod frame forwards enables the extrusion block on the inner side to push forwards through the sliding of the rolling sliding seat to enable water of the sludge in the inner part to enter the inner part of the absorption pump through extrusion, and enable the sealing frame to be communicated and upwarp to form an inlet under the lever action of the supporting plate to enable dry sludge to be discharged, and enable the water in the inner part to be conveyed upwards and collected in the water collector under the action of the upper rotating frame and the pulling rope of, the water flow is communicated and sealed through the fixing plug, the sewage is pressurized and enters the interior to be continuously mixed, stirred and softened to complete the work, so that the sludge cleaner can stir and crush overlarge sludge in the device inside when the sludge cleaner works, the sludge can be softened by adding water to prevent internal blockage, the device can be independently cleaned, and the purpose of improving the device is achieved.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic structural view of a multifunctional dredging machine for hydraulic engineering.

FIG. 2 is a schematic structural diagram of the dredging transmission device of the invention.

FIG. 3 is a detailed view of the components of the dredging transmission device.

FIG. 4 is a first schematic view of the dredging transmission device of the present invention.

FIG. 5 is a schematic diagram of the second embodiment of the dredging driving device.

In the figure: a supporting bracket-1, a mounting column-2, a dredging transmission device-3, an air valve-4, a first water inlet pipe-5, a rotary bearing seat-6, a handle bar frame-7, a cross beam frame-8, a negative pressure pump device-31, a power stirring device-32, a pressurization adjusting device-33, a water absorption transmission device-34, an extrusion discharging device-35, a mixing rotating device-36, a jointer-311, a fixed base-312, a mud inlet pipe-313, a pipe body-314, a power supply box-315, a negative pressure fan-316, a mud outlet pipe-317, a central shaft-321, a propeller-322, a crushing cabin-323, a cutter-324, a transmission shaft-325, a belt pulley shaft-326, a belt-327, a driving motor-328, a water pump device-31, a power supply box-, A driving shaft-329, a meshing gear-3210, a pressurizing cabin-331, a steel rope belt-332, a rubber pad-333, a fixed plug-334, a shell-335, a conveying pipe-336, a threaded seat-337, a threaded rod-338, a rotating handle-339, a top rotating rod-3310, a transfer gear-3311, a rotating disc-3312, a bevel gear-3313, a connecting rod frame-3314, an absorption pump-341, a water collector-342, a U-shaped pipe-343, a pulling rope-344, a rotating frame-345, a matching rod-346, a limiting frame-347, a sliding block-348, a matching rod frame-349, a conveying wheel-3410, a conveying rope-3411, a rotating matching wheel-3412, an auxiliary motor-3413, a squeezing cabin-351, a sealing frame-352, a shaft seat-353, a shaft seat-3413, a transmission rod, The device comprises a top rod-354, a discharge pipe-355, a plate body-356, a moving rod frame-357, a top moving connecting rod-358, a sliding shaft frame-359, a portal frame-3510, a rolling sliding seat-3511, an extrusion block-3512, a filtering layer-3513, a mixing cabin-361, a feeding pipe-362, a planet wheel-363, a discharging pipe-364, a sealing turntable-365, a sun wheel-366, a support plate-367 and a second water inlet pipe-368.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1 to 5, the present invention provides a technical solution of a multifunctional dredging machine for hydraulic engineering: the structure includes: the device comprises a supporting bracket 1, a mounting column 2, a dredging transmission device 3, an air valve 4, a first water inlet pipe 5, a rotating bearing seat 6, a handle rod frame 7 and a cross beam frame 8, wherein the two air valves 4 are parallel to each other and are welded into an integrated structure through the supporting bracket 1 vertical to the inner side surface, the rotating bearing seat 6 is fixedly mounted on the upper surface of the supporting bracket 1 in a welding mode, the rotating bearing seat 6 is vertically connected with the rear side of the upper surface of the air valve 4 and is of an integrated structure with the air valve, the cross beam frame 8 is embedded into the inner side surface of the rotating bearing seat 6 and is connected with the rotating bearing seat in a clearance fit mode, the mounting column 2 is positioned above the cross beam frame 8 and is movably connected with the cross beam frame 8, the dredging transmission device 3 is positioned in the vertical direction of the mounting column 2 and is welded into an integrated structure with the mounting column, the first water inlet pipe 5 is arranged above the dredging transmission device, the handle bar frame 7 is positioned on the lower surface of the cross beam frame 8 and is of an integrated structure with the cross beam frame;

the dredging transmission device 3 is provided with a negative pressure pump device 31, a power stirring device 32, a pressurization adjusting device 33, a water absorption transmission device 34, an extrusion discharging device 35 and a mixing rotating device 36;

the mixing and rotating device 36 is arranged in the center of the lower surface of the equipment and fixedly connected with the lower surface of the equipment, the power stirring device 32 is vertically connected to the left side of the lower surface of the mixing and rotating device 36 and is communicated with the lower surface of the mixing and rotating device 36, the negative pressure pump device 31 is vertically embedded into the power stirring device 32 and is connected with the negative pressure pump device by welding, the pressurization adjusting device 33 is arranged at the left side end of the upper surface of the mixing and rotating device 36 and is communicated with the inside of the mixing and rotating device 36, the extrusion discharging device 35 is arranged at the upper right side of the mixing and rotating device 36 and is connected into an integrated structure by a pipeline, the water absorption transmission device 34 is arranged on the upper surface of the extrusion discharging device 35, the water absorption transmission device and the extrusion discharging device are vertical to each other, the negative pressure pump device 31 is provided with a connector 311, the negative pressure fan 316 is positioned on the upper surface of the fixed base 312 and forms an integrated structure, the power supply box 315 is positioned on the right side surface of the negative pressure fan 316 and is electrically connected with the right side surface of the negative pressure fan, the negative pressure fan 316 is positioned on the front surface of the pipe 314 and is vertically embedded into the pipe 314 to be in clearance fit with the pipe, the lower end of the mud inlet pipe 313 positioned on the inner side of the pipe 314 is fixed into an integrated structure by welding, the mud outlet pipe 317 and the mud inlet pipe 313 are parallel to each other and are integrated with the pipe 314, the adapter 311 is positioned on the rear side surface of the mud outlet pipe 317 and wraps the mud outlet pipe 317, the power stirring device 32 is provided with a central shaft 321, a propeller 322, a crushing cabin 323, a cutter 324, a transmission shaft 325, a belt pulley shaft 326, a belt 321327, a driving motor 328, a driving shaft 329 and a meshing gear 0, the central shaft 321 is vertically positioned on the upper end of, the cutter 324 and the left and right sides of the central shaft 321 form an integrated structure by welding, the outer end of the lower surface of the central shaft 321 is wrapped by the propeller 322 and is integrated with the outer end of the lower surface of the central shaft 321, the transmission shaft 325 is vertically extended upwards from the central shaft 321 and is movably connected together, the pulley shaft 326 is vertical to the upper surface of the transmission shaft 325 and is meshed together, the pulley shaft 326 is matched into an integrated structure by a belt 327 positioned on the outer surface of the pulley shaft, the driving shaft 329 is vertically embedded into the inner surface of the driving motor 328 and is in clearance fit with the driving motor 328, the meshing gear 3210 is vertically connected to the right side surface of the driving shaft 329, the pressurization adjusting device 33 is provided with a pressurization cabin 331, a steel rope 332, a rubber pad 333, a fixed plug 334, a shell 335, a delivery pipe 336, a screw seat, A jacking rod 3310, a transit gear 3311, a rotary plate 3312, a bevel gear 3313, a link rod 3314, wherein the bevel gear 3313 and the transit gear 3311 are parallel to each other and engaged with the transit gear 3311 to form an integrated structure, the transit gear 3311 and the rotary plate 3312 are concentric and formed into an integrated structure through a shaft, the link rod 3314 is positioned on the upper surface of the transit gear 3311 and the bevel gear 3313 to form an integrated structure, the jacking rod 3310 penetrates through the pressurizing chamber 331 and is connected with a rubber pad 333 positioned inside the pressurizing chamber 331, the rubber pad 333 is in clearance fit with the inner surface of the pressurizing chamber 331, the steel rope belt 332 wraps the outer surface of the rotary plate 3312, the delivery pipe 336 is embedded in the pressurizing chamber 331 and is fixedly connected with the pressurizing chamber 331, the delivery pipe 336 is positioned inside the housing 335 and is formed into an integrated structure, the fixing plug 334 wraps the lower surface of the threaded rod 338 and is movably fitted with the fixing plug, the threaded rod 338 penetrates through the upper surface of the threaded seat 337 and is in threaded connection with the threaded seat 337, the rotating handle 339 is perpendicular to the upper surface of the threaded rod 338 and is welded with the threaded rod 338 to form an integrated structure, the water absorption transmission device 34 is provided with an absorption pump 341, a water collector 342, a U-shaped pipe 343, a pulling rope 344, a rotating frame 345, a matching rod 346, a limiting frame 347, a sliding block 348, a matching rod frame 349, a conveying wheel 3410, a conveying rope 3411, a rotating matching wheel 3412 and an auxiliary motor 3413, the absorption pump 341 is positioned on the right side surface of the U-shaped pipe 343 and is communicated with the U-shaped pipe 343, the U-shaped pipe 343 is positioned on the upper surface of the water collector 342 and is movably connected with the water collector 342, the pulling rope 344 is positioned on the upper surface of the absorption pump 341 and is welded with the absorption pump 341 to form an integrated structure, the lower surface of the rotating frame 345 is provided with the pulling rope 344, the rotating frame 345 is mounted on the upper surface of, the sliding block 348 is embedded in the inner side surface of the limiting frame 347 and is in clearance fit with the limiting frame 347, the fitting rod frame 349 is positioned below the fitting rod 346 and is fixedly connected with the sliding block 348, the lower end of the fitting rod frame 349 is installed on the front surface of the conveying wheel 3410, the conveying wheel 3410 and the rotating fitting wheel 3412 form an integrated structure through the conveying rope 3411, the auxiliary motor 3413 is perpendicular to the lower surface of the rotating fitting wheel 3412 and is meshed with the rotating fitting wheel 3412, the extrusion discharging device 35 is provided with an extrusion chamber 351, a sealing frame 352, a shaft seat 353, a top rod 354, a discharging pipe 355, a plate body 356, a moving rod frame 357, a pushing connecting rod 358, a sliding shaft frame 359, a portal frame 3510, a rolling slide 3511, a squeezing block 3512 and a filtering layer 3513, the pushing connecting rod 358 is positioned on the right side surface of the moving rod frame 357 and forms an integrated structure through the sliding shaft frame 359, the sliding shaft bracket 359 is fixedly installed at the center of the right side surface of the portal frame 3510, the rolling slide seat 3511 is located at the left side surface of the portal frame 3510 and movably connected with the portal frame 3510, the movable rod bracket 357 is matched with the rolling slide seat 3511 by clearance fit and movably connected with the front extrusion block 3512, the filter layer 3513 is arranged on the left side end surface of the extrusion chamber 351, the plate 356 is located at the lower surface of the extrusion block 3512 and movably installed on the bottom side surface of the extrusion chamber 351 through the shaft seat 353 located at the center of the lower surface, the ejector rod 354 is fixedly connected with the right side surface of the portal frame 3510 by welding, the seal frame 352 is fixedly connected with the ejector rod 354 located at the right side end surface, the discharge pipe 355 is vertically embedded into the lower surface of the extrusion chamber 351 and mutually communicated, the mixing and rotating device 36 is provided with a mixing chamber 361, The mixing device comprises a feed pipe 362, a planetary wheel 363, a discharge pipe 364, a sealing turntable 365, a sun wheel 366, a support plate 367 and a second water inlet pipe 368, wherein the second water inlet pipe 368 is vertically embedded into the left side of the upper surface of the mixing cabin 361, the feed pipe 362 and the discharge pipe 364 are parallel to each other and are simultaneously vertically embedded into the center of the lower surface of the mixing cabin 361, the sun wheel 366 is arranged in the center of the interior of the mixing cabin 361, the support plate 367 and the sun wheel 366 are circular discs with equal size and wrap the outer side of the sun wheel 366, the planetary wheel 363 is movably connected with the inner side surface of the sun wheel 366 in a meshing mode, and the sealing turntable 365 wraps the outer side of the sun wheel 366 and is welded with the.

The mixing and rotating device 36 of the invention refers to a device which can mix, feed and discharge materials by utilizing different tracks of the sun wheel and the planet wheel.

When the device is used, the device is powered on, then the air valve 4 is placed on a river channel, then the device is pushed by the handle bar frame 7, at this time, the negative pressure fan 316 is powered on, so that external sludge enters the inside of the pipe body 314 through the sludge inlet pipe 313, and simultaneously enters the inside of the crushing cabin 323 through the sludge outlet pipe 317 through the conveying of the pipe body 314, at this time, the driving motor 328 is powered on to rotate and rotate the driving shaft 329 under the action of electromagnetic induction and drive the belt wheel frame 326 on the driving shaft 329 to rotate, the central shaft 321 below is driven to rotate through the rotation of the belt 327 so that the cutter 324 and the propeller 322 below rotate to crush large dirt inside the sludge, and the sludge enters the inside of the mixing cabin 361 below through the feeding pipe 362, at this time, the bevel gear 3313 in front is driven to rotate and drive the connecting rod frame 3314 to rotate through the rotation, the engaged transfer gear 3312 also rotates and drives the inner rubber pad 333 downwards through the link frame 3314, and the outer rotating disc 3312 and the conveying rope 332 drive the lower planetary gear 363 to rotate on the sun gear 366 and complete feeding in the rotating process, at this time, sludge is conveyed out through the discharging pipe 364 through the rotating drive, and is conveyed into the inside of the squeezing cabin 351, at the same time, the auxiliary motor 3413 rotates to drive the rotating matching wheel 3412 to rotate, so that the outer pushing link 358 rotates and pushes with the pushing link 358 and stops after the portal frame 3510 pushes the outer side surface of the column rolling slide seat 3511 forwards, then the movable rod frame 357 pushes the inner squeezing block 3512 forwards through the sliding of the rolling slide seat 3511 after continuing pushing, so that the water of the sludge in the inside is squeezed into the inside of the absorbing pump 341 through squeezing, and the sealing frame 352 is communicated and upwarps to form an inlet under the lever action of the supporting plate 356 so that dry sludge is discharged, water in the water collector is conveyed upwards and collected in the water collector 342 under the action of the absorption pump 341 on the upper rotating frame 345 and the pulling rope 344, the water flow is communicated and sealed through the fixed plug 334, and then the sewage is pressurized to enter the water collector to be continuously mixed, stirred and softened to finish the work.

The invention solves the problems that the silt cleaner can not stir up the overlarge silt in the device, the silt can not be softened by adding water to prevent internal blockage, and the device can not be cleaned independently, so that the device can not be more perfect.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (1)

1. The utility model provides a multi-functional for hydraulic engineering silt remover, its structure includes: support bracket (1), erection column (2), desilting transmission (3), pneumatic valve (4), first inlet tube (5), rotation bearing frame (6), handle lever rack (7), crossbeam frame (8), its characterized in that:

the two air valves (4) are parallel to each other and welded into an integrated structure through a supporting bracket (1) perpendicular to the inner side surface, the rotating bearing seat (6) is fixedly installed on the upper surface of the supporting bracket (1) in a welding mode, the rotating bearing seat (6) is vertically connected with the rear side of the upper surface of the air valve (4) and is of an integrated structure with the air valve, the cross beam frame (8) is embedded into the inner side surface of the rotating bearing seat (6) and is connected with the rotating bearing seat in a clearance fit mode, the mounting column (2) is located above the cross beam frame (8) and is movably connected with the cross beam frame (8), the desilting transmission device (3) is located in the vertical direction extension of the mounting column (2) and is welded into an integrated structure with the mounting column, the first water inlet pipe (5) is arranged above the desilting transmission device (3) and is communicated with the two water inlet pipes, the handle bar frame (7) is positioned on the lower surface of the cross beam frame (8) and is of an integrated structure with the cross beam frame;

the dredging transmission device (3) is provided with a negative pressure pump device (31), a power stirring device (32), a pressurization adjusting device (33), a water absorption transmission device (34), an extrusion discharging device (35) and a mixing rotating device (36);

the device comprises a mixing and rotating device (36), a power stirring device (32), a negative pressure pump device (31), a pressurization and regulation device (33), a water absorption and transmission device (34), a water discharge device (35) and a water discharge device (32), wherein the mixing and rotating device (36) is arranged in the center of the lower surface of the equipment and fixedly connected with the lower surface of the equipment, the power stirring device (32) is vertically connected to the left side of the lower surface of the mixing and rotating device (36) and communicated with the left side of the lower surface of the mixing and rotating device, the negative pressure pump device (31) is vertically embedded into the power stirring device (32) and connected with the power stirring device in a welding mode, the pressurization and regulation device (33) is positioned at the left end of the upper surface of the mixing and;

the negative pressure pump device (31) is provided with a connector (311), a fixed base (312), a mud inlet pipe (313), a pipe body (314), a power box (315), a negative pressure fan (316) and a mud outlet pipe (317);

the negative pressure fan (316) is positioned on the upper surface of the fixed base (312) and forms an integrated structure, the power supply box (315) is arranged on the right side surface of the negative pressure fan (316) and is electrically connected with the right side surface of the negative pressure fan, the negative pressure fan (316) is positioned on the front surface of the pipe body (314) and is vertically embedded into the pipe body (314) to be in clearance fit with the pipe body, the lower end of the mud inlet pipe (313) positioned on the inner side of the pipe body (314) is fixed into an integrated structure in a welding mode, the mud outlet pipe (317) and the mud inlet pipe (313) are parallel to each other and form an integrated structure with the pipe body (314), and the connector (311) is arranged on the rear side surface of the mud outlet pipe (317) and wraps the mud outlet pipe;

the power stirring device (32) is provided with a central shaft (321), a propeller (322), a crushing cabin (323), a cutter (324), a transmission shaft (325), a belt pulley shaft (326), a belt (327), a driving motor (328), a driving shaft (329) and a meshing gear (3210), wherein the central shaft (321) is vertically arranged at the upper end of the inner bottom surface of the crushing cabin (323) and is movably connected with the crushing cabin (323), the cutter (324) forms an integrated structure with the left side surface and the right side surface of the central shaft (321) in a welding mode, the outer end of the lower surface of the central shaft (321) is wrapped by the propeller (322) and is integrated with the propeller (322), the transmission shaft (325) is vertically upwards extended and movably connected with the central shaft (321), the belt pulley shaft (326) is vertical to the upper surface of the transmission shaft (325) and is meshed, the belt wheel shaft (326) is matched into an integrated structure through a belt (327) positioned on the outer side surface of the belt wheel shaft, the driving shaft (329) is vertically embedded into the inner side surface of the driving motor (328) and is in clearance fit with the driving motor (328), and the meshing gear (3210) is vertically connected to the right side surface of the driving shaft (329);

the pressurizing adjusting device (33) is provided with a pressurizing cabin (331), a steel rope belt (332), a rubber pad (333), a fixed plug (334), a shell (335), a conveying pipe (336), a threaded seat (337), a threaded rod (338), a rotating handle (339), a jacking rod (3310), a transit gear (3311), a rotating disc (3312), a bevel gear (3313) and a connecting rod frame (3314), wherein the bevel gear (3313) and the transit gear (3311) are parallel to each other and are meshed with the transit gear (3311) to form an integrated structure, the transit gear (3311) and the rotating disc (3312) are of concentric circle structures and form an integrated structure through a shaft, the connecting rod frame (3314) is positioned on the upper surfaces of the transit gear (3311) and the bevel gear (3313) to form an integrated structure, the jacking rod (3310) penetrates through the pressurizing cabin (331) and is connected with the rubber pad (333) positioned inside the pressurizing cabin (331), the rubber pad (333) is in clearance fit with the inner side surface of the pressurizing cabin (331), the steel rope belt (332) wraps the outer side surface of the rotating disc (3312), the conveying pipe (336) is embedded into the pressurizing cabin (331) and fixedly connected with the pressurizing cabin (331), the conveying pipe (336) is arranged in the shell (335) and is of an integrated structure, the fixing plug (334) wraps the lower surface of the threaded rod (338) and is movably matched with the lower surface of the threaded rod, the threaded rod (338) penetrates through the upper surface of the threaded seat (337) and is in threaded connection with the threaded seat (337), and the rotating handle (339) is perpendicular to the upper surface of the threaded rod (338) and is welded with the threaded rod (338) to form an integrated structure;

the water absorption and transmission device (34) is provided with an absorption pump (341), a water collector (342), a U-shaped pipe (343), a pulling rope (344), a rotating frame (345), a matching rod (346), a limiting frame (347), a sliding block (348), a matching rod frame (349), a conveying wheel (3410), a conveying rope (3411), a rotating matching wheel (3412) and an auxiliary motor (3413), wherein the absorption pump (341) is positioned on the right side surface of the U-shaped pipe (343) and communicated with the right side surface of the U-shaped pipe, the U-shaped pipe (343) is arranged on the upper surface of the water collector (342) and movably connected with the water collector, the pulling rope (344) is positioned on the upper surface of the absorption pump (341) and welded with the absorption pump (341) to form an integrated structure, the lower surface of the rotating frame (345) is provided with the pulling rope (344), the rotating frame (345) is arranged on the upper surface of the sliding block (348) through the matching rod (346) positioned, the sliding block (348) is embedded in the inner side surface of the limiting frame (347) and is in clearance fit with the inner side surface of the limiting frame, the matching rod frame (349) is positioned below the matching rod (346) and is fixedly connected with the sliding block (348), the lower end of the matching rod frame (349) is installed on the front surface of the conveying wheel (3410), the conveying wheel (3410) and the rotating matching wheel (3412) form an integrated structure through a conveying rope (3411), and the auxiliary motor (3413) is perpendicular to the lower surface of the rotating matching wheel (3412) and is meshed with the rotating matching wheel (3412);

the extrusion discharging device (35) is provided with an extrusion chamber (351), a sealing frame (352), a shaft seat (353), a mandril (354), a discharging pipe (355), a plate body (356), a moving rod frame (357), a pushing connecting rod (358), a sliding shaft frame (359), a portal frame (3510), a rolling sliding seat (3511), an extrusion block (3512) and a filter layer (3513), wherein the pushing connecting rod (358) is positioned on the right side surface of the moving rod frame (357) and forms an integrated structure by penetrating through the sliding shaft frame (359), the sliding shaft frame (359) is fixedly arranged in the center of the right side surface of the portal frame (3510), the rolling sliding seat (3511) is positioned on the left side surface of the portal frame (3510) and movably connected with the portal frame (3510), the moving rod frame (357) is matched with the rolling sliding seat (3511) in a clearance fit way and movably connected with the extrusion block (3512) in front, the filter layer (3513) is arranged on the left side end face of the extrusion chamber (351), the plate body (356) is positioned on the lower surface of the extrusion block (3512) and is movably arranged on the bottom side surface of the extrusion chamber (351) through a shaft seat (353) positioned in the center of the lower surface of the extrusion block, the ejector rod (354) is fixedly connected with the right side surface of the portal frame (3510) in a welding mode, the sealing frame (352) is fixedly connected with the ejector rod (354) positioned on the right side end face of the sealing frame, and the discharge pipe (355) is vertically embedded into the lower surface of the extrusion chamber (351) and is communicated with the extrusion chamber;

the mixing rotating device (36) is provided with a mixing cabin (361), a feeding pipe (362), a planet wheel (363), a discharging pipe (364), a sealing turntable (365), a sun wheel (366), a support plate (367) and a second water inlet pipe (368), the second water inlet pipe (368) is vertically embedded into the left side of the upper surface of the mixing cabin (361), the feed pipe (362) and the discharge pipe (364) are parallel to each other and are vertically embedded in the center of the lower surface of the mixing chamber (361), the sun wheel (366) is arranged in the center of the interior of the mixing cabin (361), the support plate (367) and the sun wheel (366) are disks with equal size and wrap the outer side of the sun wheel (366), the planet wheels (363) are positioned on the inner side surface of the sun wheel (366) and are movably connected together in a meshing way, the seal rotor (365) wraps around the outside of the sun gear (366) and is welded thereto as a unitary structure.

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