CN113550316A - Grouting device for hydraulic engineering construction - Google Patents

Abstract

The invention discloses a grouting device for hydraulic engineering construction, which comprises a pulping device, wherein an up-and-down reciprocating device is arranged in the pulping device; through slurrying device, make this cementer can prefabricate the thick liquid in advance, conveniently change thick liquid concentration, can not lead to the grout process to be interrupted because of changing thick liquid concentration, help increasing grouting efficiency, through slurrying device, reciprocating device from top to bottom, weighing device, the containing device, aggregate's cooperation, make this cementer can the concentration of real-time detection prefabricate the thick liquid, do not need the people to get the water and the aggregate of appointed proportional quantity, the work load is little, the degree of accuracy is high, help increasing grouting efficiency and quality, through the blowing device, make prefabricated thick liquid can drop into the grout operation, through slurrying device, beat the device, transmission's cooperation, make the aggregate can spill into aquatic gradually with the form of waterfall, help making water and aggregate form even quality thick liquid, the practicality of this cementer for hydraulic engineering construction has been improved.

Description

Grouting device for hydraulic engineering construction

Technical Field

The invention relates to the field of grouting equipment for hydraulic engineering, in particular to a grouting device for hydraulic engineering construction.

Background

The hydraulic engineering is an engineering built for controlling and allocating surface water and underground water in the nature to achieve the purpose of removing harm and benefiting, also called water engineering, water is a valuable resource essential for human production and life, but the naturally existing state of the water does not completely meet the requirement of human, only the hydraulic engineering is built to control water flow and prevent flood disasters and adjust and distribute water quantity to meet the requirement of people on water resources in life and production, the hydraulic engineering needs to build dams, dikes, spillways, water gates, water inlets, channels, crossing troughs, rafts, fishways and other different types of hydraulic buildings to achieve the aim, a certain proportion of slurry is required to be filled into foundation pores, cracks or seams and cracks of the buildings per se at proper pressure during the construction of the hydraulic engineering, the work is grouting, specifically, grouting is carried out by drilling or embedding a pipe, grouting with fluidity and gelling property is pressed into a stratum or a gap of a building according to a certain proportion requirement, and cementing and hardening are carried out into a whole, so as to achieve the engineering purposes of seepage prevention, consolidation and reinforcement.

The grouting device for the existing hydraulic engineering construction mainly comprises a stirring device, a pressurizing device, a grouting device and the like, when in use, firstly, a certain amount of water is manually measured and added into the stirring device, then, a specified amount of aggregate is measured according to the mixing ratio and added into the stirring device, then, the stirring device is started, then, the stirring device uniformly mixes the water and the aggregate to form slurry, then, the pressurizing device presses the slurry into the grouting device, and then, the grouting device presses the slurry into a drill hole for grouting operation, but the process of manually measuring the water and the aggregate according to the mixing ratio is more complicated, the workload is higher, the slurry concentration error is easy to cause due to misoperation, the grouting efficiency and quality are influenced, the slurry cannot be prefabricated, the slurry concentration is inconvenient to replace, the grouting process is easy to interrupt in the process of replacing the slurry concentration, the grouting efficiency is lower, meanwhile, the aggregate is easy to form lumps by manually adding the aggregate into the water at one time, the formation of homogeneous slurry is not easy, so that the grouting device for hydraulic engineering construction needs to be designed urgently.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the existing grouting device for hydraulic engineering construction in the prior art, which mainly comprises a stirring device, a pressurizing device, a grouting device and the like, when in use, firstly, a certain amount of water is manually measured and added into the stirring device, then, a specified amount of aggregate is measured according to the mixture ratio and added into the stirring device, then, the stirring device is started, then, the stirring device uniformly mixes the water and the aggregate to form slurry, then, the pressurizing device presses the slurry into the grouting device, and then, the grouting device presses the slurry into a drill hole for grouting operation, but the process of manually measuring the water and the aggregate according to the mixture ratio is more complicated, the workload is larger, the concentration error of the slurry is larger due to misoperation, the grouting efficiency and quality are influenced, the slurry cannot be prefabricated, the concentration of the slurry is inconvenient to be changed, the grouting process is easy to be interrupted in the process of changing the concentration of the slurry, and the grouting efficiency is lower, meanwhile, the aggregate is easily formed into lumps by artificially adding the aggregate into water at one time, and homogeneous slurry is not easily formed.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

The grouting device for the hydraulic engineering construction comprises a slurrying device, wherein an up-and-down reciprocating device is arranged in the slurrying device.

Preferably, the pulping device comprises a bearing vehicle plate, universal wheels are fixedly mounted on the bottom surface of the bearing vehicle plate, a right reinforcing column is fixedly connected to the top surface of the bearing vehicle plate, the right reinforcing column is positioned at the right end of the bearing vehicle plate, an equipment box is fixedly connected to the top end of the right reinforcing column, a pressure pipe positioned at the bottom end of the equipment box is fixedly connected to the left side surface of the equipment box, the left end of the pressure pipe inclines downwards and is fixedly connected with the left end of the bearing vehicle plate, a reducing pipe is fixedly communicated with the left end of the pressure pipe, a grouting pipe is fixedly communicated with the left end of the reducing pipe, a pressure worm is movably inserted into the pressure pipe and is slidably connected with the inner wall of the pressure pipe, the top end of the pressure worm extends into the equipment box and is fixedly connected with a driven bevel gear, a heightening block positioned at the right end of the equipment box is fixedly connected to the bottom surface of an inner cavity of the equipment box, and a driving motor is fixedly mounted on the top surface of the heightening block, the outer part of an output shaft on the driving motor is fixedly sleeved with a driving bevel gear, the driving bevel gear is meshed with a driven bevel gear, the inner wall of an equipment box is fixedly connected with a separation plate positioned above the driving motor, the right side surface of the equipment box is fixedly inserted with an intelligent controller positioned above the separation plate, the right side surface of the equipment box is fixedly connected with a displacement handle positioned at the top part of the equipment box, the left side surface of the equipment box is fixedly connected with a grouting box, the bottom end of the grouting box is fixedly buckled on the outer surface of a pressure pipe, the inner wall of the grouting box is fixedly connected with a guide inclined plate, the left end of the guide inclined plate is fixedly connected on the left side surface of an inner cavity of the grouting box, the right end of the guide inclined plate is fixedly connected on the surface of the pressure pipe, the top surface of the pressure pipe is provided with a grouting hole positioned at the right side of the guide inclined plate, the bottom surface of the grouting box is fixedly connected with a left reinforcing column, the bottom end of the left reinforcing column is fixedly connected on the top surface of a bearing vehicle plate, a stirring rod positioned above the guide inclined plate is movably sleeved on the left side surface of the inner cavity of the grouting box, the right end of the stirring rod extends into the equipment box and is fixedly connected with the end part of an output shaft on the driving motor, a stirring rod positioned in the grouting box is fixedly sleeved on the outer part of the stirring rod, a stirring barrel positioned above the grouting box is fixedly connected on the left side surface of the equipment box, a cavity separating plate is fixedly connected on the inner wall of the stirring barrel, a stirring motor is fixedly installed on the top surface of the stirring barrel, the bottom end of the output shaft on the stirring motor extends into the stirring barrel and is fixedly connected with a stirring rod, the bottom end of the stirring rod penetrates through the cavity separating plate and is movably sleeved on the bottom surface of the inner cavity of the stirring barrel, a stirring rod positioned below the cavity separating plate is fixedly sleeved on the outer part of the stirring rod, a feeding hopper is fixedly inserted and connected at the upper right corner of the stirring barrel, the feeding hopper is fixedly communicated with the stirring barrel, and the bottom end of the feeding hopper is fixedly inserted and connected on the cavity separating plate, the left side surface of the stirring barrel is fixedly communicated with a water injection pipe located below the separation cavity plate, an electronic flowmeter is arranged on a pipeline of the water injection pipe, the other end of the water injection pipe is fixedly communicated with a conveying water pump, and a water inlet on the conveying water pump is fixedly communicated with a water pumping pipe.

Preferably, the up-down reciprocating device comprises a fixed pipe, a reciprocating thread groove and a reciprocating sleeve, the top end of the fixed pipe is fixedly connected to the top surface of the inner cavity of the stirring barrel and movably sleeved outside the stirring rod, a right-angled triangle groove is formed in the bottom surface of the fixed pipe, the reciprocating thread groove is formed in the surface of the stirring rod and located above the cavity separating plate, the reciprocating sleeve is movably sleeved outside the stirring rod, a displacement column is fixedly connected to the inner wall of the reciprocating sleeve, the other end of the displacement column is movably inserted inside the reciprocating thread groove, a bearing ring located at the bottom end of the reciprocating sleeve is fixedly sleeved outside the reciprocating sleeve, a torsion spring is movably sleeved outside the reciprocating sleeve, the bottom end of the torsion spring is fixedly connected to the top surface of the bearing ring, a torsion sleeve located above the torsion spring is movably sleeved outside the reciprocating sleeve, and the bottom surface of the torsion sleeve is fixedly connected to the top end of the torsion spring, the right side surface of the inner cavity of the twisting sleeve is provided with a bent groove, the inner part of the bent groove is movably inserted with a limiting stop pin, one end of the limiting stop pin is fixedly connected on the surface of the reciprocating sleeve, the left side surface of the inner cavity of the twisting sleeve is provided with an arc-shaped groove, the inner wall of the arc-shaped groove is connected with a reset stop pin through a reset spring in a transmission way, the reset stop pin is connected with the inner wall of the arc-shaped groove in a sliding way, one end of the reset stop pin is fixedly connected with the surface of the reciprocating sleeve, the right side surface of the twisting sleeve is fixedly connected with an L-shaped guide rod, the other end of the L-shaped guide rod is movably inserted on a cavity separating plate, the cavity separating plate is provided with an arc-shaped hole for the displacement of the L-shaped guide rod, the left side surface of the twisting sleeve is fixedly connected with a positioning rod, the top surface of the twisting sleeve is fixedly connected with a bearing plate, the bearing plate is movably sleeved outside the reciprocating sleeve, and the top surface of the bearing plate is fixedly connected with a right-angle triangular block, the right triangle block is matched with the right triangle groove.

Preferably, the device also comprises a weighing device, the weighing device comprises an insulating block, the right side surface of the insulating block is fixedly connected to the left end of the positioning rod, a cylindrical cavity is formed in the insulating block, a flat guide pipe is fixedly connected to the top surface of the inner cavity of the cylindrical cavity, an insulating guide strip is movably inserted in the flat guide pipe, a fixed tooth socket is formed in the left side surface of the insulating guide strip, a linkage disk is fixedly connected to the bottom end of the insulating guide strip, a linkage column is fixedly connected to the bottom surface of the linkage disk, a weighing spring is movably sleeved outside the linkage column, the top end of the weighing spring is fixedly connected to the bottom surface of the linkage disk, the bottom end of the weighing spring is fixedly connected to the bottom surface of the inner cavity of the cylindrical cavity, the bottom end of the linkage column extends to the outside of the insulating block and penetrates through a partition cavity plate, the linkage column is movably inserted in the partition cavity plate, an arc hole for displacement of the linkage column is formed in the partition plate, a semicircular groove is formed in the left side surface of the inner cavity of the cylindrical cavity, offer the first cambered surface that is located its top and inlay the dress groove on semicircular groove's the inner wall, the inside fixed dress that first cambered surface inlays the dress groove is equipped with the arc conducting strip, offer the second cambered surface that is located its bottom on semicircular groove's the inner wall and inlay the dress groove, the inside fixed dress that the second cambered surface inlays the dress groove is equipped with the arc resistance piece, insulating trip bar has been cup jointed in the activity on semicircular groove's the inner wall, the external fixation of insulating trip bar has cup jointed electrically conductive gear, electrically conductive gear and fixed tooth's socket meshing, electrically conductive gear's the first electrically conductive shell fragment of fixedly connected with and the electrically conductive shell fragment of second on the surface, the other end of first electrically conductive shell fragment and the sliding surface connection of arc conducting strip, the other end of the electrically conductive shell fragment of second and the sliding surface connection of arc resistance piece.

Preferably, the container also comprises a containing device, the containing device comprises a fixed box, the fixed box is fixedly sleeved outside the linkage column, the bottom end of the linkage column is fixedly connected to the bottom surface of the inner cavity of the fixed box, the left side surface of the inner cavity of the fixed box is movably sleeved with a rotary rod positioned at the top end of the inner cavity of the fixed box, the right end of the rotary rod is fixedly sleeved with a rotary gear, the rotary gear is movably inserted on the top surface of the fixed box, the left side surface of the fixed box is movably inserted with a turnover shaft positioned at the bottom end of the fixed box, the left end of the turnover shaft is fixedly connected with a containing hopper, the right end of the turnover shaft extends into the inner part of the fixed box and is movably sleeved on the left side surface of the linkage column, the surface of the turnover shaft is fixedly connected with a limit stop positioned in the fixed box, the bottom surface of the inner cavity of the fixed box is fixedly connected with a positioning stop matched with the limit stop, the outside of the turnover shaft is fixedly sleeved with a driven gear positioned on the right side of the limit stop, driven gear and rotating gear meshing, the external fixation of trip shaft has cup jointed the reel that is located the driven gear right side, and the outside winding of reel has the universal driving line, and the other end fixedly connected with of universal driving line holds the power spring, holds the top fixed connection of power spring and holds on the top surface of fixed incasement chamber.

Preferably, the gear box further comprises a linkage device, the linkage device comprises a fixed perforation, the fixed perforation is arranged on the cavity separating plate, an arc-shaped shifting flat cylinder is movably inserted into the inside of the fixed perforation, displacement sliding holes are formed in the left side surface and the right side surface of the arc-shaped shifting flat cylinder, the bottom surface of the inner cavity of the arc-shaped shifting flat cylinder is connected with a guide piston through a compression spring in a transmission mode, the guide piston is connected with the inner wall of the arc-shaped shifting flat cylinder in a sliding mode, a fixing wing piece is fixedly connected to the side surface of the guide piston, the other end of the fixing wing piece penetrates through the displacement sliding holes and is fixedly connected to the inner wall of the fixed perforation, an arc-shaped linkage rack is fixedly connected to the end face of the bottom end of the arc-shaped shifting flat cylinder, and the arc-shaped linkage rack is matched with the rotating gear.

Preferably, the device also comprises a material placing device, the material placing device comprises a reinforcing plate, the top surface of the reinforcing plate is fixedly connected to the bottom end of the stirring barrel, the right end of the reinforcing plate is fixedly connected to the left side surface of the equipment box, the bottom surface of the reinforcing plate is fixedly connected to the top surface of the grouting box, a positioning slide hole is formed in the left side surface of the reinforcing plate, a material placing hole for penetrating the reinforcing plate is formed in the reinforcing plate, the material placing hole is fixedly communicated with the stirring barrel, the grouting box and the positioning slide hole, a piston plate is inserted in the positioning slide hole in a sliding manner, a fixing through hole for penetrating the piston plate is formed in the piston plate, the fixing through hole is matched with and staggered with the material placing hole, a bearing flat box is fixedly connected to the left side surface of the reinforcing plate, the right end of the bearing flat box is fixedly connected to the left side surface of the stirring barrel, the bottom surface of the bearing flat box is fixedly connected to the top surface of the grouting box, a water conveying pump bolt is fixed to the top surface of the bearing flat box, fixedly connected with tractive pole on the left surface of piston plate, the other end of tractive pole extends to the inside and the fixedly connected with tractive circle that bear the flat case, fixedly connected with tractive spring on the right flank of tractive circle, the right-hand member fixed connection of tractive spring is on the left surface of gusset plate, fixedly connected with strong magnetic column on the left surface of tractive circle, the outside activity of strong magnetic column has cup jointed the partition plate, partition plate fixed connection is on the inner wall that bears the flat case, fixedly connected with electro-magnet on the left surface that bears the flat case inner chamber, electro-magnet and strong magnetic column looks adaptation.

Preferably, still including the rapping device, the rapping device is including strengthening the riser, the bottom fixed connection of strengthening the riser is on the top surface of equipment box, the top fixed connection of strengthening the riser is on the bottom surface of loading hopper, the activity is pegged graft on the strengthening riser has the upset stick, the external fixation of upset stick has cup jointed the upset disc, the external activity of upset stick has cup jointed the torsion elastic component, the one end of torsion elastic component and the fixed surface of upset disc are connected, the other end fixed connection of torsion elastic component is on the surface of strengthening the riser, the pole is beaten to colluding the type that fixedly connected with is located its lower left corner department on the surface of upset disc, the other end fixedly connected with who beats the pole to colluding the type beats the ball, beat ball and loading hopper looks adaptation.

Preferably, the device also comprises a transmission device, the transmission device comprises a transmission column, a positioning shaft, an overturning hole and a locking plate, the transmission column is movably inserted on the top surface of the equipment box, the top end of the transmission column is fixedly connected with an inclined plane column, the top surface of the inclined plane column is provided with a bearing cavity, corners on the hook type rapping rod are movably inserted in the bearing cavity and are in contact connection with the bottom surface of the inner cavity of the bearing cavity, the bottom end of the transmission column is movably inserted on the isolation plate, a bearing hole is formed in the transmission column, the top surface of the inner cavity of the bearing hole is connected with a force application piston through a force application spring in a transmission way, the force application piston is in sliding connection with the inner wall of the bearing hole, the bottom surface of the force application piston is fixedly connected with a force application column, the bottom end of the force application column extends to the outside of the transmission column and is fixedly sleeved with a transmission bevel gear, the transmission bevel gear is meshed with the driving bevel gear, and the surface of the transmission column is provided with a positioning hole fixedly communicated with the bearing hole, the surface of the force application piston is fixedly connected with a transmission column head, the other end of the transmission column head penetrates through the positioning hole and is fixedly connected with a displacement ring, the displacement ring is movably sleeved outside the transmission column, the bottom end of the displacement ring is fixedly connected with a positioning tube, the positioning tube is movably sleeved outside the transmission column, the bottom end of the positioning tube is movably sleeved with a rotating ring, the rotating ring is movably sleeved outside the transmission column, the positioning shaft is movably sleeved on the inner wall of the equipment box and is positioned on the right side of the transmission column, the outside of the positioning shaft is fixedly sleeved with a lever disc, the outside of the positioning shaft is movably sleeved with a lever spring, one end of the lever spring is fixedly connected on the inner wall of the equipment box, the other end of the lever spring is fixedly connected on the surface of the lever disc, the left side surface of the lever disc is fixedly connected with a U-shaped buckling piece, the U-shaped buckling piece is movably buckled outside the transmission column and is in contact connection with the bottom surface of the rotating ring, the utility model discloses a locking plate's equipment box, including the equipment box, the right-hand member of lever disc is connected with the application of force lever that is located its upper right corner department on the surface, the upset hole is seted up on the right flank of equipment box and is located the below of intelligent control ware, the right-hand member of application of force lever passes the upset hole and fixed the cup joint has the locking retaining ring, lockplate fixed connection just is located the below in upset hole on the right flank of equipment box, fixedly connected with locking spring on the top surface of lockplate, the top fixedly connected with locking ring of locking spring, locking ring and locking retaining ring looks adaptation.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

the grouting device for the hydraulic engineering construction can prefabricate slurry in advance through the slurry preparing device, is convenient for replacing the slurry concentration, does not cause the interruption of the grouting process due to the replacement of the slurry concentration, is beneficial to increasing the grouting efficiency, the grouting device for the hydraulic engineering construction can detect the concentration of the prefabricated slurry in real time by matching the slurry preparing device, the up-down reciprocating device, the weighing device, the containing device and the linkage device, does not need to manually measure water and aggregate with specified proportional quantity, has small workload and high accuracy, is beneficial to increasing the grouting efficiency and quality, the prefabricated slurry can be put into grouting operation through the discharging device, the aggregate can be gradually sprayed into water in a waterfall form through the matching of the pulping device, the beating device and the transmission device, the water and the aggregate are made to form homogeneous slurry, and the practicability of the grouting device for hydraulic engineering construction is improved.

Drawings

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

FIG. 2 is a schematic view of the internal structure of FIG. 1 according to the present invention;

FIG. 3 is a schematic view of the vertical reciprocating device of FIG. 2;

FIG. 4 is a schematic view of the internal structure of FIG. 3 according to the present invention;

FIG. 5 is a top view of the positive stop pin of FIG. 4 in accordance with the present invention;

FIG. 6 is a schematic diagram of the internal structure of the weighing apparatus of FIG. 2 according to the present invention;

FIG. 7 is a schematic view of FIG. 2 at 4 according to the present invention;

FIG. 8 is a schematic view showing the internal structure of the fixing box of FIG. 7 according to the present invention;

FIG. 9 is a schematic view of the internal structure of the linkage of FIG. 2 according to the present invention;

FIG. 10 is a schematic view of the internal structure of the feeding device shown in FIG. 2 according to the present invention;

fig. 11 is a schematic view of the internal structure of the rapping device in fig. 2 in accordance with the present invention;

FIG. 12 is a schematic view of the internal structure of the drive column of FIG. 11 according to the present invention;

FIG. 13 is a schematic view of the locking plate of the present invention.

The reference numbers in the figures illustrate:

1. a pulping device; 101. a carrier board; 102. a universal wheel; 103. a right reinforcing column; 104. an equipment box; 105. a pressurizing pipe; 106. a reducer; 107. grouting pipes; 108. a pressure worm; 109. a driven bevel gear; 110. a block for raising; 111. a drive motor; 112. a drive bevel gear; 113. a separator plate; 114. an intelligent controller; 115. a displacement handle; 116. grouting box; 117. a material guiding inclined plate; 118. grouting holes; 119. a left reinforcement column; 120. a stirring rod; 121. a disturbance rod; 122. a stirring barrel; 123. a cavity separating plate; 124. a stirring motor; 125. a stirring rod; 126. a stirring rod; 127. a hopper; 128. a water injection pipe; 129. an electronic flow meter; 130. a delivery water pump; 131. a water pumping pipe; 2. an up-and-down reciprocating device; 200. a fixed tube; 201. a right triangle groove; 202. a reciprocating thread groove; 203. a reciprocating sleeve; 204. a displacement column; 205. a bearing ring; 206. a torsion spring; 207. twisting the sleeve; 208. bending the groove; 209. a limit stop pin; 210. an arc-shaped groove; 211. a return spring; 212. resetting the stop pin; 213. an L-shaped guide rod; 214. positioning a rod; 215. a carrier tray; 216. a right-angled triangular block; 3. a weighing device; 301. an insulating block; 302. a cylindrical cavity; 303. a guide flat pipe; 304. insulating the guide bar; 305. fixing the tooth socket; 306. a linkage disk; 307. a linkage column; 308. weighing a spring; 309. a semicircular groove; 310. the first cambered surface is embedded with a groove; 311. an arc-shaped conducting plate; 312. the second cambered surface is embedded with a groove; 313. arc-shaped resistance cards; 314. an insulating roll-over bar; 315. a conductive gear; 316. a first conductive elastic sheet; 317. a second conductive elastic sheet; 4. a containment device; 401. a fixed box; 402. rotating the rod; 403. a rotating gear; 404. a turning shaft; 405. an accommodating bucket; 406. a limit stop block; 407. positioning a stop block; 408. a driven gear; 409. a reel; 410. a linkage line; 411. a power storage spring; 5. a linkage device; 51. fixing the through hole; 52. an arc-shaped play flat cylinder; 53. a displacement slide hole; 54. a compression spring; 55. a pilot piston; 56. a securing flap; 57. an arc-shaped linkage rack; 6. a discharging device; 601. a reinforcing plate; 602. positioning a slide hole; 603. a discharge hole; 604. a piston plate; 605. a fixing through hole; 606. carrying a flat box; 607. a traction rod; 608. pulling the ring; 609. a tension spring; 610. a ferromagnetic pillar; 611. a partition plate; 612. an electromagnet; 7. a tapping device; 71. reinforcing the vertical plate; 72. a turning bar; 73. turning over the disc; 74. a torsional elastic member; 75. a hook-type knocking rod; 76. knocking the ball; 8. a transmission device; 801. a drive post; 802. an inclined plane column; 803. a load bearing cavity; 804. a socket hole; 805. a force application spring; 806. a force application piston; 807. a force application column; 808. a drive bevel gear; 809. positioning holes; 810. a drive column head; 811. a displacement loop; 812. a positioning tube; 813. a rotating ring; 814. positioning the shaft; 815. a lever disk; 816. a lever spring; 817. a U-shaped fastener; 818. a force application lever; 819. turning over the hole; 820. locking the retainer ring; 821. a locking plate; 822. a locking spring; 823. and locking the ring.

Detailed Description

The drawings in the embodiments of the invention will be combined; the technical scheme in the embodiment of the invention is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the invention; rather than all embodiments. Based on the embodiments of the invention; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

Referring to fig. 1-13, a grouting device for hydraulic engineering construction includes a slurry making device 1, and a vertical reciprocating device 2 is disposed inside the slurry making device 1.

The pulping device 1 comprises a bearing vehicle plate 101, universal wheels 102 are fixedly installed on the bottom surface of the bearing vehicle plate 101, a right reinforcing column 103 is fixedly connected to the top surface of the bearing vehicle plate 101, the right reinforcing column 103 is located at the right end of the bearing vehicle plate 101, an equipment box 104 is fixedly connected to the top end of the right reinforcing column 103, a pressure pipe 105 located at the bottom end of the equipment box 104 is fixedly connected to the left side surface of the equipment box 104, the left end of the pressure pipe 105 inclines downwards and is fixedly connected with the left end of the bearing vehicle plate 101, a reducing pipe 106 is fixedly communicated with the left end of the pressure pipe 105, a grouting pipe 107 is fixedly communicated with the left end of the reducing pipe 106, a pressure worm 108 is movably inserted into the pressure pipe 105, the pressure worm 108 is slidably connected with the inner wall of the pressure pipe 105, the top end of the pressure worm 108 extends into the equipment box 104 and is fixedly connected with a driven bevel gear 109, a heightening block 110 located at the right end of the bottom surface of the inner cavity of the equipment box 104 is fixedly connected with the bottom surface, the top surface of the heightening block 110 is fixedly provided with a driving motor 111, the outside of an output shaft of the driving motor 111 is fixedly sleeved with a driving bevel gear 112, the driving bevel gear 112 is engaged with a driven bevel gear 109, the inner wall of the equipment box 104 is fixedly connected with a partition board 113 positioned above the driving motor 111, the right side surface of the equipment box 104 is fixedly inserted with an intelligent controller 114 positioned above the partition board 113, the right side surface of the equipment box 104 is fixedly connected with a displacement handle 115 positioned at the top thereof, the left side surface of the equipment box 104 is fixedly connected with a grouting box 116, the bottom end of the grouting box 116 is fixedly buckled on the outer surface of the pressure pipe 105, the inner wall of the grouting box 116 is fixedly connected with a material guide inclined plate 117, the left end of the material guide inclined plate 117 is fixedly connected on the left side surface of the inner cavity of the grouting box 116, the right end of the material guide inclined plate 117 is fixedly connected on the surface of the pressure pipe 105, the top surface of the pressure pipe 105 is provided with a grouting hole 118 positioned at the right side of the inclined plate 117, a left reinforcing column 119 is fixedly connected to the bottom surface of the grouting box 116, the bottom end of the left reinforcing column 119 is fixedly connected to the top surface of the carrying vehicle plate 101, a stirring rod 120 positioned above the material guiding inclined plate 117 is movably sleeved on the left side surface of the inner cavity of the grouting box 116, the right end of the stirring rod 120 extends into the equipment box 104 and is fixedly connected with the end part of the output shaft of the driving motor 111, a stirring rod 121 positioned in the grouting box 116 is fixedly sleeved outside the stirring rod 120, a stirring barrel 122 positioned above the grouting box 116 is fixedly connected to the left side surface of the equipment box 104, a cavity separating plate 123 is fixedly connected to the inner wall of the stirring barrel 122, a stirring motor 124 is fixedly mounted on the top surface of the stirring barrel 122, the bottom end of the output shaft of the stirring motor 124 extends into the stirring barrel 122 and is fixedly connected with a stirring rod 125, the bottom end of the stirring rod 125 penetrates through the cavity separating plate 123 and is movably sleeved on the bottom surface of the inner cavity of the stirring barrel 122, the outer part of the stirring rod 125 is fixedly sleeved with a stirring rod 126 positioned below the cavity separating plate 123, the upper right corner of the stirring barrel 122 is fixedly inserted with a hopper 127, the hopper 127 is fixedly communicated with the stirring barrel 122, the bottom end of the hopper 127 is fixedly inserted on the cavity separating plate 123, the left side surface of the stirring barrel 122 is fixedly communicated with a water injection pipe 128 positioned below the cavity separating plate 123, an electronic flowmeter 129 is arranged on a pipeline of the water injection pipe 128, the other end of the water injection pipe 128 is fixedly communicated with a delivery water pump 130, a water inlet on the delivery water pump 130 is fixedly communicated with a water pumping pipe 131, and the intelligent controller 114 is electrically connected with the driving motor 111, the stirring motor 124, the electronic flowmeter 129, the delivery water pump 130, the arc-shaped conductive sheet 311, the arc-shaped resistance sheet 313 and the electromagnet 612.

The up-down reciprocating device 2 comprises a fixed pipe 200, a reciprocating thread groove 202 and a reciprocating sleeve 203, the top end of the fixed pipe 200 is fixedly connected to the top surface of the inner cavity of the stirring barrel 122 and movably sleeved outside the stirring rod 125, the bottom surface of the fixed pipe 200 is provided with a right triangle groove 201, the reciprocating thread groove 202 is arranged on the surface of the stirring rod 125 and positioned above the cavity separating plate 123, the reciprocating sleeve 203 is movably sleeved outside the stirring rod 125, the inner wall of the reciprocating sleeve 203 is fixedly connected with a displacement column 204, the other end of the displacement column 204 is movably inserted inside the reciprocating thread groove 202, the outer part of the reciprocating sleeve 203 is fixedly sleeved with a bearing ring 205 positioned at the bottom end of the reciprocating sleeve 203, the outer part of the reciprocating sleeve 203 is movably sleeved with a torsion spring 206, the bottom end of the torsion spring 206 is fixedly connected to the top surface of the bearing ring 205, the outer part of the reciprocating sleeve 203 is movably sleeved with a twisting sleeve 207 positioned above the torsion spring 206, the bottom surface of the twisting sleeve 207 is fixedly connected with the top end of the torsion spring 206, the right side surface of the inner cavity of the twisting sleeve 207 is provided with a bending groove 208, the inside of the bending groove 208 is movably inserted with a limit stop pin 209, one end of the limit stop pin 209 is fixedly connected with the surface of the reciprocating sleeve 203, the left side surface of the inner cavity of the twisting sleeve 207 is provided with an arc groove 210, the inner wall of the arc groove 210 is in transmission connection with a reset stop pin 212 through a reset spring 211, the reset stop pin 212 is in sliding connection with the inner wall of the arc groove 210, one end of the reset stop pin 212 is fixedly connected with the surface of the reciprocating sleeve 203, the right side surface of the twisting sleeve 207 is fixedly connected with an L-shaped guide rod 213, the other end of the L-shaped guide rod 213 is movably inserted on the cavity separating plate 123, the cavity plate 123 is provided with an arc hole for the displacement of the L-shaped guide rod 213, the left side surface of the twisting sleeve 207 is fixedly connected with a positioning rod 214, the top surface of the twisting sleeve 207 is fixedly connected with a bearing disc 215, bear dish 215 activity cup joint in the outside of reciprocating sleeve 203, bear fixedly connected with right angle triangle-shaped piece 216 on the top surface of dish 215, right angle triangle-shaped piece 216 and right angle triangle-shaped recess 201 looks adaptation.

The weighing device comprises a weighing device 3, the weighing device 3 comprises an insulating block 301, the right side surface of the insulating block 301 is fixedly connected to the left end of the positioning rod 214, a cylindrical cavity 302 is formed in the insulating block 301, a guide flat tube 303 is fixedly connected to the top surface of the inner cavity of the cylindrical cavity 302, an insulating guide bar 304 is movably inserted in the guide flat tube 303, a fixed tooth socket 305 is formed in the left side surface of the insulating guide bar 304, a linkage disc 306 is fixedly connected to the bottom end of the insulating guide bar 304, a linkage column 307 is fixedly connected to the bottom surface of the linkage disc 306, a weighing spring 308 is movably sleeved outside the linkage column 307, the top end of the weighing spring 308 is fixedly connected to the bottom surface of the linkage disc 306, the bottom end of the weighing spring 308 is fixedly connected to the bottom surface of the inner cavity of the cylindrical cavity 302, the bottom end of the linkage column 307 extends to the outside of the insulating block 301 and penetrates through the cavity plate 123, and the linkage column 307 is movably inserted in the cavity plate 123, an arc hole for the displacement of the linkage column 307 is formed in the cavity separating plate 123, a semicircular groove 309 is formed in the left side surface of the inner cavity of the cylindrical cavity 302, a first arc embedding groove 310 located at the top of the semicircular groove is formed in the inner wall of the semicircular groove 309, an arc conducting strip 311 is fixedly embedded in the first arc embedding groove 310, a second arc embedding groove 312 located at the bottom of the semicircular groove is formed in the inner wall of the semicircular groove 309, an arc resistance sheet 313 is fixedly embedded in the second arc embedding groove 312, an insulating turnover rod 314 is movably sleeved on the inner wall of the semicircular groove 309, a conducting gear 315 is fixedly sleeved on the outer portion of the insulating turnover rod 314, the conducting gear 315 is meshed with the fixed tooth groove 305, a first conducting elastic sheet 316 and a second conducting elastic sheet 317 are fixedly connected to the surface of the conducting gear 315, the other end of the first conducting elastic sheet 316 is connected with the surface of the arc conducting strip 311 in a sliding mode, and the other end of the second conducting elastic sheet 317 is connected with the surface of the arc resistance sheet 313 in a sliding mode.

The device further comprises a containing device 4, the containing device 4 comprises a fixed box 401, the fixed box 401 is fixedly sleeved outside a linkage column 307, the bottom end of the linkage column 307 is fixedly connected to the bottom surface of the inner cavity of the fixed box 401, a rotating rod 402 positioned at the top end of the fixed box 401 is movably sleeved on the left side surface of the inner cavity of the fixed box 401, a rotating gear 403 is fixedly sleeved at the right end of the rotating rod 402, the rotating gear 403 is movably inserted on the top surface of the fixed box 401, a turning shaft 404 positioned at the bottom end of the fixed box 401 is movably inserted on the left side surface of the fixed box 401, a containing bucket 405 is fixedly connected to the left end of the turning shaft 404, the right end of the turning shaft 404 extends into the fixed box 401 and is movably sleeved on the left side surface of the linkage column 307, a limit stop 406 positioned in the fixed box 401 is fixedly connected to the surface of the turning shaft 404, and a positioning stop 407 matched with the limit stop is fixedly connected to the bottom surface of the inner cavity of the fixed box 401, a driven gear 408 positioned on the right side of the limit stop 406 is fixedly sleeved outside the overturning shaft 404, the driven gear 408 is meshed with the rotating gear 403, a winding wheel 409 positioned on the right side of the driven gear 408 is fixedly sleeved outside the overturning shaft 404, a linkage wire 410 is wound outside the winding wheel 409, the other end of the linkage wire 410 is fixedly connected with a force storage spring 411, and the top end of the force storage spring 411 is fixedly connected to the top surface of the inner cavity of the fixed box 401.

The device comprises a linkage device 5, the linkage device 5 comprises a fixed through hole 51, the fixed through hole 51 is arranged on a cavity separating plate 123, an arc-shaped shifting flat cylinder 52 is movably inserted into the fixed through hole 51, displacement sliding holes 53 are formed in the left side surface and the right side surface of the arc-shaped shifting flat cylinder 52, the bottom surface of the inner cavity of the arc-shaped shifting flat cylinder 52 is connected with a guide piston 55 through a compression spring 54 in a transmission mode, the guide piston 55 is connected with the inner wall of the arc-shaped shifting flat cylinder 52 in a sliding mode, a fixing wing piece 56 is fixedly connected to the side surface of the guide piston 55, the other end of the fixing wing piece 56 penetrates through the displacement sliding holes 53 and is fixedly connected to the inner wall of the fixed through hole 51, an arc-shaped linkage rack 57 is fixedly connected to the end face of the bottom end of the arc-shaped shifting flat cylinder 52, and the arc-shaped linkage rack 57 is matched with a rotating gear 403.

The device also comprises a discharging device 6, the discharging device 6 comprises a reinforcing plate 601, the top surface of the reinforcing plate 601 is fixedly connected to the bottom end of the stirring barrel 122, the right end of the reinforcing plate 601 is fixedly connected to the left side surface of the equipment box 104, the bottom surface of the reinforcing plate 601 is fixedly connected to the top surface of the grouting box 116, the left side surface of the reinforcing plate 601 is provided with a positioning slide hole 602, the reinforcing plate 601 is internally provided with a discharging hole 603 for penetrating the reinforcing plate, the discharging hole 603 is fixedly communicated with the stirring barrel 122, the grouting box 116 and the positioning slide hole 602, the positioning slide hole 602 is internally provided with a piston plate 604 in a sliding insertion manner, the piston plate 604 is provided with a fixing through hole 605 for penetrating the piston plate, the fixing through hole 605 is matched with and staggered with the discharging hole 603, the left side surface of the reinforcing plate 601 is fixedly connected with a bearing flat box 606, the right end of the bearing flat box 606 is fixedly connected to the left side surface of the stirring barrel 122, the bottom surface of the bearing flat box 606 is fixedly connected to the top surface of the grouting box 116, the conveying water pump 130 is fixed on the top surface of the bearing flat box 606 through bolts, a pulling rod 607 is fixedly connected to the left side surface of the piston plate 604, the other end of the pulling rod 607 extends into the bearing flat box 606 and is fixedly connected with a pulling ring 608, a pulling spring 609 is fixedly connected to the right side surface of the pulling ring 608, the right end of the pulling spring 609 is fixedly connected to the left side surface of the reinforcing plate 601, a strong magnetic column 610 is fixedly connected to the left side surface of the pulling ring 608, a partition plate 611 is movably sleeved outside the strong magnetic column 610 and is fixedly connected to the inner wall of the bearing flat box 606, an electromagnet 612 is fixedly connected to the left side surface of the inner cavity of the bearing flat box 606, and the electromagnet 612 is matched with the strong magnetic column 610.

Still including rapping device 7, rapping device 7 is including strengthening riser 71, the bottom fixed connection of strengthening riser 71 is on the top surface of equipment box 104, the top fixed connection of strengthening riser 71 is on the bottom surface of loading hopper 127, it has upset stick 72 to peg graft in the activity on the strengthening riser 71, upset disc 73 has been cup jointed to the external fixation of upset stick 72, torsion elastic component 74 has been cup jointed in the external activity of upset stick 72, the one end of torsion elastic component 74 and the fixed surface of upset disc 73 are connected, the other end fixed connection of torsion elastic component 74 is on the surface of strengthening riser 71, the pole 75 is beaten to colluding the type that is located its lower left corner to fixed connection on the surface of upset disc 73, the other end fixedly connected with who beats pole 75 beats the type beats the ball 76, beat ball 76 and loading hopper 127 looks adaptation.

The device further comprises a transmission device 8, the transmission device 8 comprises a transmission column 801, a positioning shaft 814, an overturning hole 819 and a locking plate 821, the transmission column 801 is movably inserted on the top surface of the equipment box 104, the top end of the transmission column 801 is fixedly connected with an inclined plane column 802, the top surface of the inclined plane column 802 is provided with a bearing cavity 803, a corner on the hook-shaped knocking rod 75 is movably inserted inside the bearing cavity 803 and is in contact connection with the bottom surface of the inner cavity of the bearing cavity, the bottom end of the transmission column 801 is movably inserted on the isolation plate 113, the transmission column 801 is internally provided with a bearing hole 804, the top surface of the inner cavity of the socket hole 804 is in transmission connection with a force application piston 806 through a force application spring 805, the force application piston 806 is in sliding connection with the inner wall of the socket hole 804, the bottom surface of the force application piston 806 is fixedly connected with a force application column 807, the bottom end of the force application column 807 extends to the outside of the transmission column 801 and is fixedly sleeved with a transmission bevel gear 808, the transmission bevel gear 808 is meshed with the driving bevel gear 112, the surface of the transmission column 801 is provided with a positioning hole 809 fixedly communicated with the socket hole 804, the surface of the force application piston 806 is fixedly connected with a transmission column head 810, the other end of the transmission column head 810 penetrates through the positioning hole 809 and is fixedly connected with a displacement ring 811, the displacement ring 811 is movably sleeved outside the transmission column 801, the bottom end of the displacement ring 811 is fixedly connected with a positioning pipe 812, the positioning pipe 812 is movably sleeved outside the transmission column 801, the bottom end of the positioning pipe 812 is movably sleeved with a rotating ring 813, the rotating ring 813 is movably sleeved outside the transmission column 801, the positioning shaft 814 is movably sleeved on the inner wall of the equipment box 104 and is positioned at the right side of the transmission column 801, the outside of the positioning shaft 814 is fixedly sleeved with a lever disc 815, the outside of the positioning shaft 814 is movably sleeved with a lever spring 816, one end of the lever spring 816 is fixedly connected on the inner wall of the equipment box 104, the other end of the lever spring 816 is fixedly connected on the surface of the lever disc 815, the left side surface of the lever disc 815 is fixedly connected with a U-shaped buckling member 817, the U-shaped buckling member 817 is movably buckled outside the transmission column 801 and is in contact connection with the bottom surface of the rotating ring 813, the surface of the lever disc 815 is fixedly connected with a force application lever 818 located at the upper right corner of the lever disc 815, the turnover hole 819 is formed in the right side surface of the equipment box 104 and is located below the intelligent controller 114, the right end of the force application lever 818 penetrates through the turnover hole 819 and is fixedly sleeved with a locking retaining ring 820, the locking plate 821 is fixedly connected to the right side surface of the equipment box 104 and is located below the turnover hole 819, the top surface of the locking plate 821 is fixedly connected with a locking spring 822, the top end of the locking spring 822 is fixedly connected with a locking ring 823, and the locking ring 823 is matched with the locking retaining ring 820.

The working principle is as follows:

firstly, the intelligent controller 114 turns on the power supply of the stirring motor 124, then the stirring motor 124 drives the stirring rod 125 to rotate, then the stirring rod 125 drives the stirring rod 126 to rotate, meanwhile, the stirring rod 125 drives the reciprocating sleeve 203 to move upwards through the cooperation of the reciprocating thread groove 202 and the displacement column 204, then the reciprocating sleeve 203 drives the twisting sleeve 207 to move upwards through the limit stop pin 209 and the reset stop pin 212, then the twisting sleeve 207 drives the L-shaped guide rod 213, the positioning rod 214, the bearing disc 215 and the right-angle triangular block 216 to move upwards, then the positioning rod 214 drives the weighing device 3 and the containing device 4 to move upwards, then the rotating gear 403 is meshed with the arc-shaped linkage rack 57, then the rotating gear applies upward thrust to the arc-shaped linkage rack 57, then the arc-shaped linkage rack 57 drives the arc-shaped play flat cylinder 52 to move upwards and apply work to the compression spring 54, the compression spring 54 is elastically compressed, the elastic potential energy is increased, then the right-angled triangle block 216 continues to move upwards, then the top end of the right-angled triangle block 216 is contacted with the inner wall of the right-angled triangle groove 201, then the inner wall of the right-angled triangle groove 201 applies a twisting force to the right-angled triangle block 216, then the right-angled triangle block 216 drives the bearing disc 215 and the twisting sleeve 207 to rotate anticlockwise by taking the reciprocating sleeve 203 as a central shaft, then the twisting sleeve 207 drives the L-shaped guide rod 213 and the positioning rod 214 to rotate anticlockwise, then the positioning rod 214 drives the weighing device 3 and the accommodating device 4 to rotate anticlockwise, then the rotating gear 403 moves relative to the arc-shaped linkage rack 57, then the rotating gear 403 rotates by taking the rotating rod 402 as a central shaft under the meshing action between the rotating gear 403 and the arc-shaped linkage rack 57, then the rotating gear 403 rotates by taking the overturning shaft 404 under the meshing action between the rotating gear 403 and the driven gear 408, then the turning shaft 404 drives the containing bucket 405, the limit stop 406 and the winding wheel 409 to rotate, then the limit stop 406 is separated from the positioning stop 407, the linkage line 410 winds and pulls the power storage spring 411 to the outside of the winding wheel 409, then the power storage spring 411 is elastically stretched, the elastic potential energy is increased, then the displacement column 204 is upwards displaced to the highest position, at the moment, the containing bucket 405 turns over by one hundred eighty degrees by taking the turning shaft 404 as a central axis, then the displacement column 204 drives the reciprocating sleeve 203 to downwards move under the matching action between the displacement column and the reciprocating thread groove 202, then the reciprocating sleeve 203 drives the twisting sleeve 207 to downwards move through the limit stop pin 209 and the reset stop pin 212, then the twisting sleeve 207 drives the L-shaped guide rod 213, the positioning rod 214, the bearing disc 215 and the triangular right-angle block 216 to downwards move, then the positioning rod 214 drives the weighing device 3 and the containing device 4 to downwards move, and simultaneously the arc-shaped float flat cylinder 52 drives the arc-shaped linkage rack 57 to downwards under the elastic repulsive force of the compression spring 54, then a gap is formed between the right triangle block 216 and the inner wall of the right triangle groove 201, then the torsion spring 206 applies torsion to the twisting sleeve 207, meanwhile the return spring 211 applies torsion to the twisting sleeve 207, then the twisting sleeve 207 drives the L-shaped guide rod 213, the positioning rod 214, the bearing disc 215 and the right triangle block 216 to reversely rotate under the action of the torsion, then the positioning rod 214 drives the weighing device 3 and the accommodating device 4 to reversely rotate by taking the reciprocating sleeve 203 as a central shaft, then the rotating gear 403 drives the rotating rod 402 to reversely rotate by taking the rotating rod 402 as a central shaft under the action of meshing with the arc-shaped linkage rack 57, then the rotating gear 403 drives the overturning shaft 404 to reversely rotate by the meshing action of the rotating gear 403 and the driven gear 408, then the overturning shaft 404 drives the accommodating bucket 405, the limit stop 406 and the reel 409 to reversely rotate, so that the accommodating bucket 405 gradually returns, in the process, the power storage spring 411 pulls the linkage line 410 under the action of self elasticity, then the linkage line 410 is released from the outside of the reel 409 and drives it to rotate reversely, then the reel 409 provides assistance for the rotation of the turning shaft 404, then the right triangle block 216 is separated from the right triangle groove 201, then the arc linkage rack 57 is separated from the rotary gear 403, then the displacement column 204 is displaced downwards to the lowest point position, at this time the limit stop 406 is contacted with the positioning stop 407, the containing bucket 405 is completely reset and reaches the lowest point, the above is repeated, the containing bucket 405 is moved up and down in a reciprocating manner, then the delivery water pump 130 is started through the intelligent controller 114, then the outside water enters the space of the stirring barrel 122 below the cavity partition 123 through the water pumping pipe 131, the delivery water pump 130, the water injection pipe 128 and the electronic flow meter 129, then the electronic flow meter 129 meters the water amount entering the stirring barrel 122 until the water amount reaches the set value, then the intelligent controller 114 closes the delivery water pump 130, stopping water injection, pouring aggregate into a hopper 127, allowing part of the aggregate to pass through an opening at the bottom end of the hopper 127 under the action of self gravity and fall on the water surface, quickly mixing the aggregate with the water by a rotating stirring rod 126, starting a driving motor 111 through an intelligent controller 114, driving a stirring rod 121 to rotate by the driving motor 111 through a stirring rod 120, driving a pressurizing worm 108 to rotate by the driving motor 111 through the meshing action of a driving bevel gear 112 and a driven bevel gear 109, driving the driving motor 111 through the meshing action of the driven bevel gear 109 and a driving bevel gear 808, a force application column 807, a force application piston 806, a driving column head 810, a positioning hole 809 and a transmission column 801 to drive a bevel column 802 to rotate, periodically applying upward thrust to a hook-type knocking rod 75 by the rotating bevel column 802, and when the hook-type knocking rod 75 is subjected to upward thrust, the hooking beating rod 75 with the beating ball 76 and the turnover disc 73 is turned clockwise around the turnover rod 72 as a central shaft, then the thrust on the hooking beating rod 75 disappears, then the hooking beating rod 75 and the beating ball 76 are beaten on the inclined plane of the hopper 127 under the action of inertia force and generate vibration to provide assistance for the flowing of the aggregates, then the turnover disc 73 is reset under the action of the torsion elastic element 74 through the hooking beating rod 75 with the beating ball 76, the reciprocating is carried out in such a way, the beating ball 76 repeatedly beats the inclined plane of the hopper 127 to promote the aggregates to be gradually added into the water system, then the water and the aggregates are uniformly mixed to form slurry, then the slurry enters the accommodating hopper 405 when the accommodating hopper 405 is at the lowest point position, then the accommodating hopper 405 moves upwards and is separated from the slurry in the stirring barrel 122, at this time, the accommodating hopper 405 is filled with the slurry inside the accommodating hopper 405, and then the accommodating hopper 405 increases the gravity of the accommodating device 4 under the action of the gravity of the slurry inside, then the containing device 4 pulls the linkage column 307, then the linkage column 307 carries the linkage disc 306 and the insulating guide strip 304 to move downwards, then the linkage disc 306 applies work to the weighing spring 308, then the weighing spring 308 is elastically shortened, the elastic potential energy is increased, then the insulating guide strip 304 drives the first conductive elastic sheet 316 and the second conductive elastic sheet 317 to turn clockwise by taking the insulating turning rod 314 as a central shaft through the meshing action of the fixed tooth socket 305 and the conductive gear 315, then the length of the arc-shaped resistor disc 313 connected into the circuit is shortened, the current is increased, then the intelligent controller 114 obtains the concentration of the slurry in the containing bucket 405 according to the current magnitude, then the containing bucket 405 turns over one hundred eighty degrees to pour the slurry into the slurry in the stirring barrel 122, then the containing bucket 405 is reset and filled with new slurry, the steps are repeated, the concentration of the slurry in the stirring barrel 122 is detected in real time, then the concentration of the slurry in the stirring barrel 122 reaches the requirement, then the intelligent controller 114 gives an alarm, then downward pressure is applied to the force application lever 818, then the force application lever 818 rotates clockwise with the U-shaped fastener 817 carried by the lever disc 815 and applies upward thrust to the rotating ring 813, then the U-shaped fastener 817 moves upward with the driving bevel gear 808 through the rotating ring 813, the positioning tube 812, the displacement ring 811, the driving column head 810, the force application piston 806 and the force application column 807, then the driving bevel gear 808 separates from the driving bevel gear 112, then the beating ball 76 stops beating the charging hopper 127, then the aggregate does not enter the stirring barrel 122, then the locking check ring 820 passes through the locking ring 823, then the locking ring 823 is sleeved outside the force application lever 818, then the locking spring 822 applies downward pressure to the force application lever 818 through the locking ring 823 under the action of the self-elastic force, so that the separated state of the driving bevel gear 808 and the driving bevel gear 112 is fixed, then the electromagnet 612 is controlled to be electrified through the intelligent controller 114, then the electromagnet 612 generates electromagnetic force, then the ferromagnetic column 610 moves leftwards under the action of electromagnetic attraction, then the ferromagnetic column 610 drives the piston plate 604 to move leftwards through the pulling ring 608 and the pulling rod 607, then the discharging hole 603 is aligned with the fixed through hole 605, at this time, the ferromagnetic column 610 is in butt joint with the electromagnet 612, then the grout inside the stirring barrel 122 enters the grouting box 116 through the discharging hole 603 and the fixed through hole 605, then the grout enters the pressurizing pipe 105 through the grouting hole 118 and enters the grouting device for grouting through the reducing pipe 106 and the grouting pipe 107 under the pushing of the pressurizing worm 108, and then the grouting is finished.

The above; but are merely preferred embodiments of the invention; the scope of the invention is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the invention are equally replaced or changed; are intended to be covered by the scope of the present invention.

Claims (9)

1. The utility model provides a cementer for hydraulic engineering construction, includes slurrying device (1), its characterized in that: the pulping device (1) is internally provided with an up-down reciprocating device (2).

2. The grouting device for hydraulic engineering construction according to claim 1, characterized in that: the pulping device (1) comprises a bearing vehicle plate (101), universal wheels (102) are fixedly mounted on the bottom surface of the bearing vehicle plate (101), a right reinforcing column (103) is fixedly connected to the top surface of the bearing vehicle plate (101), the right reinforcing column (103) is located at the right end of the bearing vehicle plate (101), an equipment box (104) is fixedly connected to the top end of the right reinforcing column (103), a pressure pipe (105) is fixedly connected to the bottom end of the equipment box (104) on the left side surface of the equipment box (104), the left end of the pressure pipe (105) inclines downwards and is fixedly connected with the left end of the bearing vehicle plate (101), a reducing pipe (106) is fixedly communicated to the left end of the pressure pipe (105), a grouting pipe (107) is fixedly communicated to the left end of the reducing pipe (106), a pressure worm (108) is movably inserted into the pressure pipe (105), the pressure worm (108) is connected with the inner wall of the pressure pipe (105) in a sliding manner, and the top end of the pressure worm (108) extends to the inside of the equipment box (104) and is fixedly connected with a driven bevel gear (109) The bottom surface of the inner cavity of the equipment box (104) is fixedly connected with a heightening block (110) positioned at the right end of the inner cavity, the top surface of the heightening block (110) is fixedly provided with a driving motor (111), the outer part of an output shaft of the driving motor (111) is fixedly sleeved with a driving bevel gear (112), the driving bevel gear (112) is meshed with a driven bevel gear (109), the inner wall of the equipment box (104) is fixedly connected with a partition plate (113) positioned above the driving motor (111), the right side surface of the equipment box (104) is fixedly inserted with an intelligent controller (114) positioned above the partition plate (113), the right side surface of the equipment box (104) is fixedly connected with a displacement handle (115) positioned at the top of the equipment box, the left side surface of the equipment box (104) is fixedly connected with a grouting box (116), the bottom end of the grouting box (116) is fixedly buckled on the outer surface of a pressure pipe (105), the inner wall of the grouting box (116) is fixedly connected with a material guide plate (117), the left end of the guide sloping plate (117) is fixedly connected to the left side surface of the inner cavity of the grouting box (116), the right end of the guide sloping plate (117) is fixedly connected to the surface of the pressure pipe (105), the top surface of the pressure pipe (105) is provided with a grouting hole (118) positioned at the right side of the guide sloping plate (117), the bottom surface of the grouting box (116) is fixedly connected with a left reinforcing column (119), the bottom end of the left reinforcing column (119) is fixedly connected to the top surface of the bearing plate (101), the left side surface of the inner cavity of the grouting box (116) is movably sleeved with a stirring rod (120) positioned above the guide sloping plate (117), the right end of the stirring rod (120) extends into the equipment box (104) and is fixedly connected with the end part of an output shaft on the driving motor (111), the outer part of the stirring rod (120) is fixedly sleeved with a stirring rod (121) positioned inside the grouting box (116), the left side surface of the equipment box (104) is fixedly connected with a stirring barrel (122) positioned above the grouting box (116), a cavity separating plate (123) is fixedly connected on the inner wall of the stirring barrel (122), a stirring motor (124) is fixedly installed on the top surface of the stirring barrel (122), the bottom end of an output shaft on the stirring motor (124) extends to the inside of the stirring barrel (122) and is fixedly connected with a stirring rod (125), the bottom end of the stirring rod (125) penetrates through the cavity separating plate (123) and is movably sleeved on the bottom surface of the inner cavity of the stirring barrel (122), a stirring rod (126) positioned below the cavity separating plate (123) is fixedly sleeved outside the stirring rod (125), a feeding hopper (127) is fixedly inserted at the upper right corner of the stirring barrel (122), the feeding hopper (127) is fixedly communicated with the stirring barrel (122), the bottom end of the feeding hopper (127) is fixedly inserted on the cavity separating plate (123), a water injection pipe (128) positioned below the cavity separating plate (123) is fixedly communicated on the left side surface of the stirring barrel (122), and an electronic flowmeter (129) is arranged on a pipeline of the water injection pipe (128), the other end of the water injection pipe (128) is fixedly communicated with a delivery water pump (130), and a water pumping pipe (131) is fixedly communicated with a water inlet on the delivery water pump (130).

3. The grouting device for hydraulic engineering construction according to claim 2, characterized in that: the up-and-down reciprocating device (2) comprises a fixed pipe (200), a reciprocating thread groove (202) and a reciprocating sleeve (203), the top end of the fixed pipe (200) is fixedly connected to the top surface of the inner cavity of the stirring barrel (122) and movably sleeved outside the stirring rod (125), a right-angled triangular groove (201) is formed in the bottom surface of the fixed pipe (200), the reciprocating thread groove (202) is formed in the surface of the stirring rod (125) and located above the cavity partition plate (123), the reciprocating sleeve (203) is movably sleeved outside the stirring rod (125), a displacement column (204) is fixedly connected to the inner wall of the reciprocating sleeve (203), the other end of the displacement column (204) is movably inserted inside the reciprocating thread groove (202), a bearing ring (205) located at the bottom end of the reciprocating sleeve (203) is fixedly sleeved outside the reciprocating sleeve, and a torsion spring (206) is movably sleeved outside the reciprocating sleeve (203), the bottom end of a torsion spring (206) is fixedly connected to the top surface of a bearing ring (205), a twisting sleeve (207) positioned above the torsion spring (206) is movably sleeved outside a reciprocating sleeve (203), the bottom surface of the twisting sleeve (207) is fixedly connected with the top end of the torsion spring (206), a bending groove (208) is formed in the right side surface of an inner cavity of the twisting sleeve (207), a limiting stop pin (209) is movably inserted in the bending groove (208), one end of the limiting stop pin (209) is fixedly connected to the surface of the reciprocating sleeve (203), an arc groove (210) is formed in the left side surface of the inner cavity of the twisting sleeve (207), the inner wall of the arc groove (210) is connected with a resetting stop pin (212) in a transmission mode through a resetting spring (211), the resetting stop pin (212) is connected with the inner wall of the arc groove (210) in a sliding mode, one end of the resetting stop pin (212) is fixedly connected with the surface of the reciprocating sleeve (203), fixedly connected with L type guide arm (213) on the right flank of wrench movement sleeve pipe (207), the other end activity of L type guide arm (213) is pegged graft on separating chamber board (123), the arc hole that supplies L type guide arm (213) displacement is seted up on separating chamber board (123), fixedly connected with locating lever (214) on the left surface of wrench movement sleeve pipe (207), fixedly connected with bears dish (215) on the top surface of wrench movement sleeve pipe (207), bear the outside of dish (215) activity cup joint at reciprocating sleeve pipe (203), fixedly connected with right triangle-shaped block (216) on the top surface of bearing dish (215), right triangle-shaped block (216) and right triangle-shaped groove (201) looks adaptation.

4. The grouting device for hydraulic engineering construction according to claim 3, characterized in that: the device comprises an insulating block (301), the right side face of the insulating block (301) is fixedly connected to the left end of a positioning rod (214), a cylindrical cavity (302) is formed in the insulating block (301), a guide flat tube (303) is fixedly connected to the top face of the inner cavity of the cylindrical cavity (302), an insulating guide strip (304) is movably inserted into the inner portion of the guide flat tube (303), a fixing tooth slot (305) is formed in the left side face of the insulating guide strip (304), a linkage disc (306) is fixedly connected to the bottom end of the insulating guide strip (304), a linkage column (307) is fixedly connected to the bottom face of the linkage disc (306), a weighing spring (308) is movably sleeved on the outer portion of the linkage column (307), the top end of the weighing spring (308) is fixedly connected to the bottom face of the linkage disc (306), the bottom end of the weighing spring (308) is fixedly connected to the bottom face of the inner cavity of the cylindrical cavity (302), the bottom end of the linkage column (307) extends to the outside of the insulating block (301) and penetrates through the cavity separating plate (123), the linkage column (307) is movably inserted into the cavity separating plate (123), an arc-shaped hole for displacement of the linkage column (307) is formed in the cavity separating plate (123), a semicircular groove (309) is formed in the left side surface of the inner cavity of the cylindrical cavity (302), a first arc-shaped embedded groove (310) located at the top of the semicircular groove is formed in the inner wall of the semicircular groove (309), an arc-shaped conducting strip (311) is fixedly embedded in the first arc-shaped embedded groove (310), a second arc-shaped embedded groove (312) located at the bottom of the semicircular groove is formed in the inner wall of the semicircular groove (309), an arc-shaped resistance strip (313) is fixedly embedded in the inner wall of the second arc-shaped embedded groove (312), an insulating turnover rod (314) is movably sleeved on the inner wall of the semicircular groove (309), and a conductive gear (315) is fixedly sleeved on the outside of the insulating turnover rod (314), the conductive gear (315) is meshed with the fixed tooth slot (305), a first conductive elastic sheet (316) and a second conductive elastic sheet (317) are fixedly connected to the surface of the conductive gear (315), the other end of the first conductive elastic sheet (316) is in sliding connection with the surface of the arc-shaped conductive sheet (311), and the other end of the second conductive elastic sheet (317) is in sliding connection with the surface of the arc-shaped resistor sheet (313).

5. The grouting device for hydraulic engineering construction according to claim 4, characterized in that: the device comprises a fixed box (401), the fixed box (401) is fixedly sleeved outside a linkage column (307), the bottom end of the linkage column (307) is fixedly connected to the bottom surface of the inner cavity of the fixed box (401), a rotating rod (402) positioned at the top end of the inner cavity of the fixed box (401) is movably sleeved on the left side surface of the inner cavity of the fixed box (401), a rotating gear (403) is fixedly sleeved at the right end of the rotating rod (402), the rotating gear (403) is movably inserted on the top surface of the fixed box (401), a turning shaft (404) positioned at the bottom end of the fixed box (401) is movably inserted on the left side surface of the fixed box (401), a containing hopper (405) is fixedly connected to the left end of the turning shaft (404), the right end of the turning shaft (404) extends to the inside of the fixed box (401) and is movably sleeved on the left side surface of the linkage column (307), a limit stop (406) positioned inside the fixed box (401) is fixedly connected to the surface of the turning shaft (404), fixedly connected with and limit stop (406) looks adaptation's location dog (407) on the bottom surface of fixed case (401) inner chamber, the external fixation of trip shaft (404) has cup jointed driven gear (408) that are located limit stop (406) right side, driven gear (408) and rotating gear (403) meshing, the external fixation of trip shaft (404) has cup jointed reel (409) that are located driven gear (408) right side, the outside winding of reel (409) has linkage line (410), the other end fixedly connected with of linkage line (410) holds power spring (411), the top fixed connection of holding power spring (411) is on the top surface of fixed case (401) inner chamber.

6. The grouting device for hydraulic engineering construction according to claim 5, characterized in that: the device is characterized by further comprising a linkage device (5), the linkage device (5) comprises a fixed through hole (51), the fixed through hole (51) is formed in the cavity separating plate (123), an arc-shaped shifting flat cylinder (52) is movably inserted into the inside of the fixed through hole (51), displacement sliding holes (53) are formed in the left side surface and the right side surface of the arc-shaped shifting flat cylinder (52), the bottom surface of the inner cavity of the arc-shaped shifting flat cylinder (52) is connected with a guide piston (55) through a compression spring (54) in a transmission mode, the guide piston (55) is connected with the inner wall of the arc-shaped shifting flat cylinder (52) in a sliding mode, a fixing wing piece (56) is fixedly connected to the side surface of the guide piston (55), the other end of the fixing wing piece (56) penetrates through the displacement sliding holes (53) and is fixedly connected to the inner wall of the fixed through hole (51), an arc-shaped linkage rack (57) is fixedly connected to the end surface of the bottom end of the arc-shaped shifting flat cylinder (52), and the arc-shaped linkage rack (57) is matched with a rotating gear (403).

7. The grouting device for hydraulic engineering construction according to any one of claims 2 to 6, characterized in that: the material feeding device (6) further comprises a material feeding device (6), the material feeding device (6) comprises a reinforcing plate (601), the top surface of the reinforcing plate (601) is fixedly connected to the bottom end of the stirring barrel (122), the right end of the reinforcing plate (601) is fixedly connected to the left side surface of the equipment box (104), the bottom surface of the reinforcing plate (601) is fixedly connected to the top surface of the grouting box (116), the left side surface of the reinforcing plate (601) is provided with a positioning sliding hole (602), the reinforcing plate (601) is internally provided with a material discharging hole (603) which penetrates through the reinforcing plate, the material discharging hole (603) is fixedly communicated with the stirring barrel (122), the grouting box (116) and the positioning sliding hole (602), the positioning sliding hole (602) is internally inserted with a piston plate (604) in a sliding manner, the piston plate (604) is provided with a fixing through hole (605) which penetrates through the piston plate, the fixing through hole (605) is matched with the material discharging hole (603) and staggered with the discharging hole (603), and the left side surface of the reinforcing plate (601) is fixedly connected with a bearing flat box (606), the right end of the bearing flat box (606) is fixedly connected to the left side surface of the stirring barrel (122), the bottom surface of the bearing flat box (606) is fixedly connected to the top surface of the grouting box (116), the conveying water pump (130) is fixed to the top surface of the bearing flat box (606) through bolts, the left side surface of the piston plate (604) is fixedly connected with a pulling rod (607), the other end of the pulling rod (607) extends into the bearing flat box (606) and is fixedly connected with a pulling ring (608), the right side surface of the pulling ring (608) is fixedly connected with a pulling spring (609), the right end of the pulling spring (609) is fixedly connected to the left side surface of the reinforcing plate (601), the left side surface of the pulling ring (608) is fixedly connected with a strong magnetic column (610), a separating plate (611) is movably sleeved outside the strong magnetic column (610), the separating plate (611) is fixedly connected to the inner wall of the bearing flat box (606), and an electromagnet (612) is fixedly connected to the left side surface of the inner cavity of the bearing flat box (606), the electromagnet (612) is matched with the strong magnetic column (610).

8. The grouting device for hydraulic engineering construction according to claim 7, characterized in that: the automatic feeding device is characterized by further comprising a beating device (7), the beating device (7) comprises a reinforced vertical plate (71), the bottom end of the reinforced vertical plate (71) is fixedly connected to the top surface of the equipment box (104), the top end of the reinforced vertical plate (71) is fixedly connected to the bottom surface of the feeding hopper (127), a turnover rod (72) is movably inserted into the reinforced vertical plate (71), a turnover disc (73) is fixedly sleeved outside the turnover rod (72), a torsion elastic piece (74) is movably sleeved outside the turnover rod (72), one end of the torsion elastic piece (74) is fixedly connected with the surface of the turnover disc (73), the other end of the torsion elastic piece (74) is fixedly connected to the surface of the reinforced vertical plate (71), a hook-shaped beating rod (75) positioned at the lower left corner of the turnover disc (73) is fixedly connected to the surface of the turnover disc (73), and a beating ball (76) is fixedly connected to the other end of the hook-shaped beating rod (75), the knocking ball (76) is matched with the feeding hopper (127).

9. The grouting device for hydraulic engineering construction according to claim 8, characterized in that: the device comprises a transmission device (8), the transmission device (8) comprises a transmission column (801), a positioning shaft (814), an overturning hole (819) and a locking plate (821), the transmission column (801) is movably inserted into the top surface of the equipment box (104), the top end of the transmission column (801) is fixedly connected with an inclined plane column (802), the top surface of the inclined plane column (802) is provided with a bearing cavity (803), a corner on the hook-shaped knocking rod (75) is movably inserted into the bearing cavity (803) and is in contact connection with the bottom surface of the inner cavity of the bearing cavity, the bottom end of the transmission column (801) is movably inserted into the isolation plate (113), the inside of the transmission column (801) is provided with a bearing hole (804), the top surface of the inner cavity of the bearing hole (804) is connected with a force application piston (806) in a transmission mode through a force application spring (806), the force application piston (806) is in sliding connection with the inner wall of the socket hole (804), the bottom surface of the force application piston (806) is fixedly connected with a force application column (807), the bottom end of the force application column (807) extends to the outside of the transmission column (801) and is fixedly sleeved with a transmission bevel gear (808), the transmission bevel gear (808) is meshed with the driving bevel gear (112), the surface of the transmission column (801) is provided with a positioning hole (809) fixedly communicated with the bearing hole (804), the surface of the force application piston (806) is fixedly connected with a transmission column head (810), the other end of the transmission column head (810) penetrates through the positioning hole (809) and is fixedly connected with a displacement ring (811), the displacement ring (811) is movably sleeved outside the transmission column (801), the bottom end of the displacement ring (811) is fixedly connected with a positioning pipe (812), the positioning pipe (812) is movably sleeved outside the transmission column (801), the bottom end of the positioning pipe (812) is movably sleeved with a rotating ring (813), the rotating ring (813) is movably sleeved outside the transmission column (801), the positioning shaft (814) is movably sleeved on the inner wall of the equipment box (104) and is positioned on the right side of the transmission column (801), a lever disc (815) is fixedly sleeved outside the positioning shaft (814), a lever spring (816) is movably sleeved outside the positioning shaft (814), one end of the lever spring (816) is fixedly connected to the inner wall of the equipment box (104), the other end of the lever spring (816) is fixedly connected to the surface of the lever disc (815), a U-shaped buckling piece (817) is fixedly connected to the left side surface of the lever disc (815), the U-shaped buckling piece (817) is movably buckled outside the transmission column (801) and is in contact connection with the bottom surface of the rotating ring (813), a force application lever (818) located at the right upper corner of the lever disc (815) is fixedly connected to the surface of the lever disc (815), an overturning hole (819) is formed in the right side surface of the equipment box (104) and located below the intelligent controller (114), the right end of the force application lever (818) penetrates through the overturning hole (819) and is fixedly sleeved with a locking retainer ring (820), locking plate (821) fixed connection just is located the below of upset hole (819) on the right flank of equipment box (104), fixedly connected with locking spring (822) on the top surface of locking plate (821), and the top fixedly connected with locking ring (823) of locking spring (822), locking ring (823) and locking retaining ring (820) looks adaptation.

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