CN113664021B - Industrial running water muck disposal method - Google Patents

Abstract

The invention provides an industrial flowing water residual soil treatment method. The industrial flowing water residual soil treatment method comprises the following steps: pouring a proper amount of residue soil into the stirring pot; the mixing pot moves to a stirring area, curing materials are added into the muck through the matrix type high-pressure jet grouting pile, the muck is quickly cut, and the muck and the curing agents are stirred; the stirring pan continuously moves to the position above a steering mechanism along the traveling mechanism, the steering mechanism rotates to enable the stirring pan to rotate 90 degrees in situ, the moving direction of the stirring pan is changed, and the stirring pan moves to the position above the storage pool; and opening the mixing pot, pouring the muck into the storage pool by the mixing pot for maintenance, placing the muck treated every day in the same storage pool, and waiting for 7 days until the maintenance period is finished. The industrial flowing water muck disposal method provided by the invention has the advantages that the muck solidification achieves the industrial flowing water beat and the muck solidification efficiency is improved.

Description

Industrial flowing water muck disposal method

Technical Field

The invention relates to the technical field of muck disposal, in particular to an industrial flowing water muck disposal method.

Background

The residue soil is only one kind of construction waste. The residue soil refers to waste soil, waste material and other wastes generated in the process of building, rebuilding, expanding and dismantling various buildings, structures, pipe networks and the like of construction units and house decoration and decoration of residents.

At present, more and more building muck is produced in engineering construction, the muck conveying amount of a muck conveying vehicle reaches 30, when the muck needs to be solidified, the muck needs to be poured into a large-capacity mixing pot and added with a curing agent for stirring, and then the muck is maintained for 3 to 7 days.

Therefore, it is necessary to provide a new industrial method for disposing the waste soil in the flowing water to solve the above problems.

Disclosure of Invention

The invention provides an industrial flowing water muck disposal method which can realize the industrial flowing time of muck solidification and improve the muck solidification efficiency.

In order to solve the technical problems, the industrial flowing water muck disposal method provided by the invention comprises the following steps:

s1: conveying the muck to a feeding area by using a muck truck, and pouring a proper amount of muck into the mixing pot by using a conveying belt in the feeding area;

s2: after the appropriate amount of the residue soil in the stirring pot, the stirring pot moves along the traveling mechanism to move the stirring pot to a stirring area, and the matrix type high-pressure rotary spraying pile is used for quickly cutting the residue soil and stirring the residue soil and a curing agent while adding the curing material into the residue soil;

s3: after the residue soil in the stirring pan is stirred, the stirring pan continuously moves to the position above a steering mechanism along the traveling mechanism, the steering mechanism rotates to enable the stirring pan to rotate 90 degrees in situ, the moving direction of the stirring pan is changed, and the stirring pan moves to the position above a storage pool;

s4: opening the mixing pot, and pouring the muck into the storage pool for maintenance, wherein the storage pool is provided with 5 groups, the muck treated every day is placed in the same storage pool, namely, one storage pool is filled every day according to the sequence, and the maintenance period is waited for 7 days to finish; meanwhile, the storage pool which is filled with the muck 7 days ago is used for digging out the cured and solidified muck through the mechanical arm according to the sequence, the dug-out muck is crushed through a crusher, and then is conveyed to a storage bin by a crawler or is directly conveyed to a transport vehicle, and finally is conveyed to a project site to be used as various building materials;

wherein: the travelling mechanism comprises a first guide rail, a second guide rail, a driving wheel and a first variable frequency motor, the first variable frequency motor is symmetrically installed at the bottom end of the mixing pot and connected with the driving wheel, and the insides of the first guide rail and the second guide rail are connected with the driving wheel in a sliding manner; the steering mechanism comprises a turntable, rollers, fixed teeth, a first gear and a second variable frequency motor, the second guide rail is installed on the top surface of the turntable, the rollers are installed on the bottom surface of the turntable at equal intervals, the fixed teeth are installed on the side wall of the bottom end of the turntable at equal intervals, the fixed teeth are meshed with the first gear, and the first gear is installed on the top end of the second variable frequency motor; the reinforcing mechanism comprises a fixing plate, a first connecting plate, a first electromagnet, a magnet, a second electromagnet, a storage box, a fixing rod and a limiting plate, the storage box and the fixing rod are installed at the bottom end of the rotary table, the bottom ends of the storage box and the fixing rod are respectively and fixedly connected with the second electromagnet, and the top ends of the storage box and the fixing rod are respectively provided with the first electromagnet; the inner part of the storage box is connected with the fixed plate in a sliding manner, the bottom end of the mixing pot is symmetrically provided with the first connecting plates, and the side walls of the first connecting plates are connected with the fixed plate in a sliding manner; the inner parts of the fixed rod and the second guide rail are connected with the limiting plate in a sliding manner, and the limiting plate abuts against the side wall of the driving wheel; the bottom ends of the limiting plate and the fixing plate are respectively provided with the magnet, and the magnet adsorbs the first electromagnet and the second electromagnet; the power supply mechanism is arranged on the side walls of the first guide rail and the second guide rail; the connecting mechanism is arranged at the joint of the first guide rail and the second guide rail; the driving mechanism is connected with the connecting mechanism; and the adjusting mechanism is in sliding connection with the inside of the second guide rail, and the driving wheel abuts against the top end of the adjusting mechanism.

Preferably, the mixing pot comprises a main body, a base, a hydraulic cylinder and a blanking plate, and the driving wheel and the first variable frequency motor are mounted at the bottom end of the base; the base is symmetrically arranged at the bottom end of the main body; the bottom end of the main body is symmetrically and rotatably connected with the blanking plate, and two ends of the hydraulic cylinder are respectively and rotatably connected with the blanking plate and the side wall of the base.

Preferably, the power supply mechanism comprises a connecting rod, a second connecting plate, steel balls, a bracket and metal plates, the second connecting plate is respectively installed on the side walls of the first guide rail and the second guide rail, and the metal plates are symmetrically installed inside the second connecting plate; the connecting rod is installed at the bottom end of the main body, the support is installed at one end of the connecting rod, the side wall of the support is in rolling connection with the steel ball, the steel ball is in sliding connection with the side wall of the metal plate, and the steel ball is electrically connected with the first variable frequency motor.

Preferably, the connecting mechanism includes a first metal sheet, a second metal sheet, a fixed shaft, a second gear and a toothed plate, the first metal sheet and the second metal sheet are rotatably connected inside the second connecting plate located on the side wall of the first guide rail, one ends of the first metal sheet and the second metal sheet are respectively rotatably connected with the fixed shaft, one end of the fixed shaft is fixedly connected with the second gear, and the second gear and the fixed shaft are rotatably connected inside the first guide rail; the interior of the first guide rail is slidably connected with the toothed plate, and the toothed plate is engaged with the second gear.

Preferably, the driving mechanism comprises a compression rod, a slide groove, a rubber rod, a lifting plate, a limiting block and a first spring, the slide groove is formed in the side wall of the first guide rail, the compression rod and the slide rod are rotatably connected to the inside of the slide groove, the compression rod is fixedly connected to the side wall of the second guide rail, and the compression rod is slidably connected to the side wall of the slide rod; the inner part of the first guide rail is slidably connected with the elastic rubber rod, and the rubber rod with the arc-shaped side wall is abutted against the side wall of the sliding rod; the inner part of the first guide rail is slidably connected with the lifting plate, two ends of the lifting plate respectively abut against the rubber rod and the limiting block, and the limiting block is fixedly connected with the inner part of the first guide rail; the top end fixed connection of lifter plate the pinion rack, the inside symmetry installation of first guide rail first spring, first spring is contradicted the top surface of lifter plate.

Preferably, the adjusting mechanism comprises a projection, a metal rod, a metal block and a second spring, the inner sliding connection side wall of the second guide rail is the projection in a T shape, the second spring is installed in the second guide rail, and the second spring is abutted against the bottom end of the projection; the metal blocks are symmetrically arranged inside the second guide rail, the metal rods are symmetrically arranged at two ends of the convex block respectively, the metal rods abut against the metal blocks, and the metal blocks are electrically connected with the metal rods and the first electromagnets.

Compared with the related technology, the industrial flowing water muck disposal method provided by the invention has the following beneficial effects:

the invention provides an industrial flowing water muck disposal construction method, when a mixing pot moves from a first guide rail to the surface of a second guide rail, the mixing pot moves to the upper part of a rotary table, the driving wheel rotates along with the surface of the second guide rail to press an adjusting mechanism, the adjusting mechanism moves downwards, so that current flows in a first electromagnet and a second electromagnet, magnetic force is generated in the first electromagnet and the second electromagnet, the magnetic pole on the top surface of the second electromagnet is the same as that on the bottom surface of the magnet, the like poles repel each other, the magnet is pushed to move upwards in a storage box and a fixed rod, so that the magnet drives a fixed plate and a limit plate to move upwards, and the limit plate is clamped at two ends of the driving wheel, the fixing plate moves upwards to abut against the side wall of the first connecting plate, at the moment, the magnetic pole of the top surface of the magnet is opposite to the magnetic pole of the bottom surface of the first electromagnet, opposite poles attract each other, the magnet adsorbs the first electromagnet, the limiting plate and the fixing plate are fixed, the first variable frequency motor is closed, the driving wheel stops operating, the second variable frequency motor is opened to enable the first gear to rotate, the first gear pushes the fixed teeth and the turntable to rotate, the turntable drives the limiting plate and the fixing plate to rotate, and the limiting plate and the fixing plate respectively squeeze the driving wheel and the connecting plate, so that the stress area of the mixing pot is increased, the mixing pot is conveniently pushed to rotate, and the rotating direction of the mixing pot is conveniently changed; when the mixing pot moves to the position above the storage pool, the mixing pot is opened, the mixing pot is enabled to pour the dregs into the storage pool for maintenance, 5 storage pools are arranged in one group, the dregs treated every day are placed in the same storage pool, and the maintenance period is waited for 7 days to be finished; the storage pools are filled up every day according to the sequence, and meanwhile, the storage pools in which the muck is placed one day before are dug out the cured muck through the mechanical arm according to the sequence, so that the muck is cured to achieve the industrial stream rhythm and the muck curing efficiency is improved; the dug-out dregs are crushed by a crusher, then are conveyed to a storage bin by a crawler or directly conveyed to a transport vehicle, and finally are conveyed to a project site to be used as various building materials.

Drawings

FIG. 1 is a schematic structural diagram of a preferred embodiment of an industrial method for processing flowing water and dregs provided by the present invention;

FIG. 2 is a schematic view of the internal structure of the steering mechanism shown in FIG. 1;

FIG. 3 is a front view of the body construction shown in FIG. 1;

FIG. 4 is an enlarged view of the structure at A shown in FIG. 2;

FIG. 5 is an enlarged view of the structure at B in FIG. 3;

FIG. 6 is an enlarged view of the structure at C shown in FIG. 3;

FIG. 7 is a schematic view of the connection structure of the first rail and the second rail shown in FIG. 2;

fig. 8 is a schematic view of the internal structure of the first guide rail shown in fig. 7.

Reference numbers in the figures: 1. a storage pool, 2, a traveling mechanism, 21, a first guide rail, 22, a second guide rail, 23, a driving wheel, 24, a first variable frequency motor, 3, a mixing pot, 31, a main body, 32, a base, 33, a hydraulic cylinder, 34, a blanking plate, 4, a reinforcing mechanism, 41, a fixing plate, 42, a first connecting plate, 43, a first electromagnet, 44, a magnet, 45, a second electromagnet, 46, a storage box, 47, a fixing rod, 48, a limiting plate, 5, a steering mechanism, 51, a turntable, 52, a roller, 53, a fixing gear, 54, a first gear, 55, a second variable frequency motor, 6, a power supply mechanism, 61, a connecting rod, 62, a second connecting plate, 63, a steel ball, 64, a bracket, 65, a metal plate, 7, a driving mechanism, 71, a compression rod, 72, a sliding rod, 73, a sliding chute, 74, a rubber rod, 75, a lifting plate, 76, a limiting block, 77, a first spring, 8 and a connecting mechanism, 81. first sheetmetal, 82, second sheetmetal, 83, fixed axle, 84, second gear, 85, pinion rack, 9, adjustment mechanism, 91, lug, 92, metal pole, 93, metal block, 94, second spring.

Detailed Description

The invention is further described below with reference to the drawings and the embodiments.

Please refer to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7 and fig. 8 in combination, in which fig. 1 is a schematic structural diagram of a preferred embodiment of an industrial flowing water muck disposal method provided in the present invention; FIG. 2 is a schematic view of the internal structure of the steering mechanism shown in FIG. 1; FIG. 3 is a front view of the body construction shown in FIG. 1; FIG. 4 is an enlarged view of the structure at A shown in FIG. 2; FIG. 5 is an enlarged view of the structure shown at B in FIG. 3; FIG. 6 is an enlarged view of the structure at C shown in FIG. 3; FIG. 7 is a schematic view of the connection structure of the first rail and the second rail shown in FIG. 2; fig. 8 is a schematic view of the internal structure of the first guide rail shown in fig. 7. The industrial flowing water muck disposal method comprises the following steps: s1: conveying the muck to a feeding area by using a muck truck, and pouring a proper amount of muck into the mixing pot 3 by using a conveying belt in the feeding area; s2: after the appropriate amount of the residue soil in the stirring pot 3, the stirring pot 3 moves along the traveling mechanism 2, so that the stirring pot 3 moves to a stirring area, and curing materials (the mass percentage of various materials in the curing materials is 60-75 percent of nano-micron modified cementing material, 5-10 percent of polymeric aluminum ferric silicate, 10-20 percent of zeolite powder or/and bentonite and 5-15 percent of quicklime) are added into the residue soil through a matrix type high-pressure rotary spraying pile, wherein the mass percentage of the curing materials and the residue soil is 0.15 to 99.85 percent; rapidly cutting the residue soil and stirring the residue soil and the curing agent; s3: after the residue soil in the stirring pan 3 is stirred, the stirring pan 3 continues to move to the position above a steering mechanism 5 along the traveling mechanism 2, the steering mechanism 5 rotates to enable the stirring pan 3 to rotate 90 degrees in situ, the moving direction of the stirring pan 3 is changed, and the stirring pan 3 moves to the position above the storage pool 1; s4: opening the mixing pot 3, and pouring the dregs into the storage pool 1 by the mixing pot 3 for maintenance, wherein the 5 storage pools are in a group, the dregs to be treated every day are placed in the same storage pool, namely, one storage pool is filled every day according to the sequence, and the maintenance period is waited to be finished for 7 days; meanwhile, the storage pool with the muck placed in 7 days ago is used for digging out the cured muck through the mechanical arm according to the sequence, the dug-out muck is crushed through a crusher and then is conveyed to a storage bin by a crawler or directly conveyed to a transport vehicle, and finally is conveyed to a project site to be used as various building materials;

wherein: the travelling mechanism 2 comprises a first guide rail 21, a second guide rail 22, a driving wheel 23 and a first variable frequency motor 24, the first variable frequency motor 24 is symmetrically installed at the bottom end of the mixing pot 3, the first variable frequency motor 24 is connected with the driving wheel 23, and the driving wheel 23 is slidably connected inside the first guide rail 21 and the second guide rail 22; a steering mechanism 5, wherein the steering mechanism 5 comprises a turntable 51, rollers 52, fixed teeth 53, a first gear 54 and a second variable frequency motor 55, the top surface of the turntable 51 is provided with the second guide rail 22, the bottom surface of the turntable 51 is provided with the rollers 52 at equal intervals, the bottom end side wall of the turntable 51 is provided with the fixed teeth 53 at equal intervals, the fixed teeth 53 are engaged with the first gear 54, and the top end of the second variable frequency motor 55 is provided with the first gear 54; the reinforcing mechanism 4 comprises a fixing plate 41, a first connecting plate 42, a first electromagnet 43, a magnet 44, a second electromagnet 45, a storage box 46, a fixing rod 47 and a limiting plate 48, wherein the storage box 46 and the fixing rod 47 are installed at the bottom end of the rotary disc 51, the second electromagnet 45 is fixedly connected to the bottom ends of the storage box 46 and the fixing rod 47 respectively, and the first electromagnet 43 is installed at the top ends of the storage box 46 and the fixing rod 47 respectively; the fixing plate 41 is slidably connected to the inside of the storage box 46, the first connecting plates 42 are symmetrically installed at the bottom ends of the mixing pans 3, and the side walls of the first connecting plates 42 are slidably connected with the fixing plate 41; the fixing rod 47 and the inner part of the second guide rail 22 are slidably connected with the limiting plate 48, and the limiting plate 48 abuts against the side wall of the driving wheel 23; the limiting plate 48 and the bottom end of the fixing plate 41 are respectively provided with the magnet 44, and the magnet 44 adsorbs the first electromagnet 43 and the second electromagnet 45; a power supply mechanism 6, wherein the power supply mechanism 6 is mounted on the side walls of the first rail 21 and the second rail 22; a connecting mechanism 8, wherein the connecting mechanism 8 is installed at the joint of the first guide rail 21 and the second guide rail 22; the driving mechanism 7 is connected with the connecting mechanism 8, and the driving mechanism 7 is connected with the connecting mechanism 8; adjustment mechanism 9, adjustment mechanism 9 sliding connection the inside of second guide rail 22, just drive wheel 23 contradicts adjustment mechanism 9's top.

The mixing pan 3 comprises a main body 31, a base 32, a hydraulic cylinder 33 and a blanking plate 34, wherein the driving wheel 23 and the first variable frequency motor 24 are installed at the bottom end of the base 32; the bottom end of the main body 31 is symmetrically provided with the base 32; the bottom symmetry of main part 31 is rotated and is connected flitch 34 down, the both ends of pneumatic cylinder 33 are rotated respectively and are connected flitch 34 down with the lateral wall of base 32, for the convenience with the dregs pour into the inside of main part 31 stirs processing, and opens pneumatic cylinder 33, pneumatic cylinder 33 operates the shrink and drives flitch 34 down rotates down, opens main part 31, be convenient for with the inside dregs of main part 31 take out.

The power supply mechanism 6 comprises a connecting rod 61, a second connecting plate 62, steel balls 63, a bracket 64 and metal plates 65, the second connecting plate 62 is respectively installed on the side walls of the first guide rail 21 and the second guide rail 22, and the metal plates 65 are symmetrically installed inside the second connecting plate 62; the connecting rod 61 is installed at the bottom end of the main body 31, the support 64 is installed at one end of the connecting rod 61, the steel ball 63 is connected to the side wall of the support 64 in a rolling manner, the steel ball 63 is connected to the side wall of the metal plate 65 in a sliding manner, and the steel ball 63 is electrically connected to the first inverter motor 24 and the hydraulic cylinder 33, so that when the driving wheel 23 moves on the surfaces of the first guide rail 21 and the second guide rail 22, the mixing pan 3 drives the connecting rod 61, the support 64 and the steel ball 63 to move, so that the steel ball 63 rotates on the side wall of the metal plate 65, and when the mixing pan 3 moves along the first guide rail 21 and the second guide rail 22, the steel ball 63 is always in contact with the metal plate 65, so that current enters the inverter motor 24 and the hydraulic cylinder 33 through the metal plate 65 and the steel ball 63, the variable frequency motor 24 and the hydraulic cylinder 33 are operated.

The connecting mechanism 8 comprises a first metal sheet 81, a second metal sheet 82, a fixed shaft 83, a second gear 84 and a toothed plate 85, the first metal sheet 81 and the second metal sheet 82 are rotatably connected inside the second connecting plate 62 on the side wall of the first guide rail 21, one end of each of the first metal sheet 81 and the second metal sheet 82 is rotatably connected with the fixed shaft 83, one end of the fixed shaft 83 is fixedly connected with the second gear 84, and the second gear 84 and the fixed shaft 83 are rotatably connected inside the first guide rail 21; the inner portion of the first guide rail 21 is slidably connected to the toothed plate 85, and the toothed plate 85 engages the second gear 84; the driving mechanism 7 comprises a compression rod 71, a sliding rod 72, a sliding slot 73, a rubber rod 74, a lifting plate 75, a limiting block 76 and a first spring 77, the sliding slot 73 is arranged on the side wall of the first guide rail 21, the inner part of the sliding slot 73 is rotatably connected with the compression rod 71 and the sliding rod 72, the side wall of the second guide rail 22 is fixedly connected with the compression rod 71, and the compression rod 71 is slidably connected with the side wall of the sliding rod 72; the inner part of the first guide rail 21 is slidably connected with the elastic rubber rod 74, and the rubber rod 74 with an arc-shaped side wall is abutted against the side wall of the sliding rod 72; the inside of the first guide rail 21 is slidably connected with the lifting plate 75, two ends of the lifting plate 75 respectively abut against the rubber rod 74 and the limiting block 76, and the limiting block 76 is fixedly connected with the inside of the first guide rail 21; the top end of the lifting plate 75 is fixedly connected to the tooth plate 85, the first springs 77 are symmetrically installed inside the first guide rail 21, the first springs 77 abut against the top surface of the lifting plate 75, when the turntable 51 drives the second guide rail 22 to rotate and gradually align with the first guide rail 21, the second guide rail 22 drives the compression rod 71 to rotate inside the sliding groove 73, so that the compression rod 71 rotates and extrudes the sliding rod 72, the sliding rod 72 rotates and extrudes the rubber rod 74, the rubber rod 74 rotates and pushes the lifting plate 75 to move upwards and compress the first springs 77, the lifting plate 75 pushes the tooth plate 85 to move downwards inside the first guide rail 21 and push the second gear 84 to rotate, the two second gears 84 are staggered and engaged with the tooth plate 85, and when the tooth plate 85 moves upwards, the rotation directions of the two second gears 84 are opposite, the second gear 84 pushes the fixed shaft 83, the first metal sheet 81 and the second metal sheet 82 to rotate, the first metal sheet 81 rotates upwards, the second metal sheet 82 rotates downwards, the first metal sheet 81 and the second metal sheet 82 rotate to enter one side of the second guide rail 22, and when the first guide rail 21 is aligned with the second guide rail 22, the first metal sheet 81 and the second metal sheet 82 rotate to abut against the metal plate 65 on the side wall of the second guide rail 22, so that the metal plate 65 on the side wall of the first guide rail 21 is spliced with the metal plate 65 on the side wall of the second guide rail 22; when the driving wheel 23 moves from the connection between the first guide rail 21 and the second guide rail 22, the mixing pan 3 drives the steel balls 63 to slide through the side walls of the metal plate 65, the first metal sheet 81 and the second metal sheet 82, so that current continuously enters the first variable frequency motor 24 through the metal plate 65, the first metal sheet 81 and the second metal sheet 82, and the first variable frequency motor 24 continuously operates, thereby facilitating the mixing pan 3 to slide through the connection between the first guide rail 21 and the second guide rail 22.

The adjusting mechanism 9 comprises a projection 91, a metal rod 92, a metal block 93 and a second spring 94, the inner part of the second guide rail 22 is slidably connected with the projection 91 with the side wall being in a T shape, the second spring 94 is installed inside the second guide rail 22, and the second spring 94 abuts against the bottom end of the projection 91; the metal blocks 93 are symmetrically arranged inside the second guide rail 22, the metal rods 92 are symmetrically arranged at two ends of the protruding block 91 respectively, the metal rods 92 abut against the metal blocks 93, and the metal blocks 93 and the metal rods 92 are electrically connected with the first electromagnets 43 and the second electromagnets 45. In order to facilitate the movement of the driving wheel 23 on the side wall of the second guide rail 22, the driving wheel 23 is moved to compress the protrusion 91, the protrusion 91 enters the inside of the second guide rail 22 to compress the second spring 94, the protrusion 91 drives the metal rod 92 to abut against the metal block 93, so that the current flows inside the first electromagnet 43 and the second electromagnet 45, and the first electromagnet 43 and the second electromagnet 45 generate magnetic force.

When in use: firstly, the first variable frequency motor 24, the second variable frequency pad motor 55 and the metal plate 56; after the dregs in the mixing pan 3 are mixed, the first variable frequency motor 24 at the bottom end of the mixing pan 3 moves to push the driving wheel 23 to move, so that the driving wheel 23 moves along the side wall of the first guide rail 21, the mixing pan 3 gradually moves to the surface of the rotating disc 5, when the driving wheel 23 moves on the surface of the first rail 21 and the second rail 22, the mixing pot 3 drives the connecting rod 61, the bracket 64 and the steel balls 63 to move, so that the steel balls 63 rotate on the side wall of the metal plate 65, when the mixing pan 3 moves along the first guide rail 21 and the second guide rail 22, the steel balls 63 are always in contact with the metal plate 65, so that current enters the variable frequency motor 24 and the hydraulic cylinder 33 through the metal plate 65 and the steel balls 63, and the variable frequency motor 24 and the hydraulic cylinder 33 operate. When the mixing pan 3 needs to change the moving direction on the surface of the rotating disc 51, the metal block 93 is externally connected with a power supply, along with the movement of the driving wheel 23 on the second guide rail 22, the driving wheel 23 moves to compress the projection 91, so that the projection 91 enters the inside of the second guide rail 22 to compress the second spring 94, the projection 91 drives the metal rod 92 to collide with the metal block 93, when the four driving wheels 23 press all four projections 91 inside the second guide rail 22, current flows inside the first electromagnet 43 and the second electromagnet 45 at the moment, so that magnetic force is generated inside the first electromagnet 43 and the second electromagnet 45, at the moment, the magnetic pole on the top surface of the second electromagnet 45 is the same as the magnetic pole on the bottom surface of the magnet 44, and the magnets 44 are opposite in polarity, so as to push the magnet 44 to move upwards inside the storage box 46 and the fixing rod 47, so that the magnet 44 drives the fixing plate 41 and the limiting plate 48 to move upwards, the limiting plates 48 are engaged with two ends of the driving wheel 23, and the fixing plate 41 moves upwards to abut against the side wall of the first connecting plate 42, at this time, the magnetic pole of the top surface of the magnet 44 is opposite to the magnetic pole of the bottom surface of the first electromagnet 43, and opposite poles are attracted, the magnet 44 attracts the first electromagnet 43, so as to fix the limiting plate 48 and the fixing plate 41, penetrate through the first variable frequency motor 24, the driving wheel 23 stops operating, the second variable frequency motor 55 is turned on, so that the first gear 54 rotates, the first gear 54 pushes the fixing teeth 53 and the rotating disc 51 to rotate, the rotating disc 51 drives the limiting plate 48 and the fixing plate 41 to rotate, so that the limiting plate 48 and the fixing plate 41 respectively squeeze the driving wheel 23 and the first connecting plate 42, thereby increasing the stress area of the mixing pan 3 and facilitating the rotation of the mixing pan 3; when the rotating disc 51 drives the second guide rail 22 to rotate and gradually align with the first guide rail 21, the second guide rail 22 drives the compression rod 71 to rotate inside the sliding groove 73, so that the compression rod 71 rotates to press the rubber rod 74, the rubber rod 74 rotates to push the lifting plate 75 to move upwards to compress the first spring 77, the lifting plate 75 pushes the tooth plate 85 to move downwards inside the first guide rail 21 to push the second gear 84 to rotate, the two second gears 84 are staggered and meshed with the tooth plate 85, and when the tooth plate 85 moves upwards, the two second gears 84 rotate in opposite directions, the second gear 84 pushes the fixed shaft 83, the first metal sheet 81 and the second metal sheet 82 to rotate, the first metal sheet 81 rotates upwards, the second metal sheet 82 rotates downwards, and the first metal sheet 81, the second metal sheet 82 rotates downwards, Second sheetmetal 82 rotates and gets into one side of second guide rail 22, after first guide rail 21 with second guide rail 22 aligns, first sheetmetal 81 second sheetmetal 82 rotates and contradicts the metal sheet 65 of second guide rail 22 lateral wall, thereby makes first guide rail 21 lateral wall metal sheet 65 with the metal sheet 65 of second guide rail 22 lateral wall accomplishes the concatenation. The metal block 93 is reversely connected with current, the magnetic pole directions of the first electromagnet 43 and the second electromagnet 44 are changed, the magnetic pole of the bottom surface of the first electromagnet 45 is the same as the magnetic pole of the top surface of the magnet 44, the same poles repel each other, the magnet 44 is pushed to move downwards in the storage box 46 and the fixing rod 47, the fixing plate 41 and the limiting plate 48 are made to move downwards, the fixing plate 41 moves into the storage box 46 and is separated from the first connecting plate 42, the limiting plate 48 moves into the fixing rod 47 and is separated from the driving wheel 23, the first variable frequency motor 23 is opened, and the driving wheel 23 continues to move on the surface of the second guide rail 22 along the set direction. When the driving wheel 23 moves from the connection between the first guide rail 21 and the second guide rail 22, the mixing pan 3 drives the steel balls 63 to slide through the side walls of the metal plate 65, the first metal sheet 81 and the second metal sheet 82, so that current continuously enters the first variable frequency motor 24 through the metal plate 65, the first metal sheet 81 and the second metal sheet 82, and the first variable frequency motor 24 continuously operates, thereby facilitating the mixing pan 3 to slide through the connection between the first guide rail 21 and the second guide rail 22. When the mixing pot 3 moves to the position above the storage pool 1, where the muck needs to be poured, the hydraulic cylinder 33 is opened, the hydraulic cylinder 33 operates and contracts to drive the blanking plate 34 to rotate downwards, the main body 31 is opened, and the muck in the main body 31 is poured into the storage pool 1 for maintenance.

The above description is only an embodiment of the present invention, and is not intended to limit the scope of the present invention, and all equivalent structures or equivalent processes performed by the present invention or directly or indirectly applied to other related technical fields are included in the scope of the present invention.

Claims (6)

1. An industrial flowing water muck disposal method is characterized by comprising the following steps:

s1: conveying the muck to a feeding area by using a muck truck, and pouring a proper amount of muck into the mixing pot (3) by using a conveying belt in the feeding area;

s2: after the appropriate amount of the residue soil in the stirring pot (3), the stirring pot (3) moves along the traveling mechanism (2) to enable the stirring pot (3) to move to a stirring area, and the matrix type high-pressure rotary spraying pile is used for rapidly cutting the residue soil and stirring the residue soil and a curing agent while adding a curing material into the residue soil;

s3: after the residue soil in the stirring pot (3) is stirred, the stirring pot (3) continues to move to the position above a steering mechanism (5) along the traveling mechanism (2), the steering mechanism (5) rotates to enable the stirring pot (3) to rotate 90 degrees in situ, the moving direction of the stirring pot (3) is changed, and the stirring pot (3) moves to the position above the storage pool (1);

s4: opening the mixing pot (3), and pouring the dregs into the storage pool (1) by the mixing pot (3) for maintenance, wherein the storage pool (1) is divided into 5 groups, and the dregs treated every day are placed in the same storage pool (1), namely, one storage pool (1) is filled every day according to the sequence; after the 7-day curing period is finished, digging cured and solidified muck out of the storage pool (1) with muck placed in the storage pool before 7 days in sequence through the mechanical arm, crushing the dug muck through a crusher, conveying the muck to a storage bin by using a crawler or directly conveying the muck to a transport vehicle, and finally conveying the muck to a project site to be used as various building materials;

wherein: the travelling mechanism (2) comprises a first guide rail (21), a second guide rail (22), a driving wheel (23) and a first variable frequency motor (24), the first variable frequency motor (24) is symmetrically installed at the bottom end of the mixing pot (3), the first variable frequency motor (24) is connected with the driving wheel (23), and the driving wheel (23) is slidably connected with the inner parts of the first guide rail (21) and the second guide rail (22);

a steering mechanism (5), wherein the steering mechanism (5) comprises a turntable (51), a roller (52), fixed teeth (53), a first gear (54) and a second variable frequency motor (55), the second guide rail (22) is installed on the top surface of the turntable (51), the roller (52) is installed on the bottom surface of the turntable (51) at equal intervals, the fixed teeth (53) are installed on the side wall of the bottom end of the turntable (51) at equal intervals, the fixed teeth (53) are meshed with the first gear (54), and the first gear (54) is installed on the top end of the second variable frequency motor (55);

the reinforcing mechanism (4) comprises a fixing plate (41), a first connecting plate (42), a first electromagnet (43), a magnet (44), a second electromagnet (45), a storage box (46), a fixing rod (47) and a limiting plate (48), the storage box (46) and the fixing rod (47) are installed at the bottom end of the rotary disc (51), the second electromagnet (45) is fixedly connected to the bottom ends of the storage box (46) and the fixing rod (47), and the first electromagnet (43) is installed at the top ends of the storage box (46) and the fixing rod (47) respectively; the inner part of the storage box (46) is connected with the fixing plate (41) in a sliding way, the bottom end of the mixing pot (3) is symmetrically provided with the first connecting plate (42), and the side wall of the first connecting plate (42) is connected with the fixing plate (41) in a sliding way; the fixed rod (47) and the second guide rail (22) are connected with the limiting plate (48) in a sliding mode, and the limiting plate (48) abuts against the side wall of the driving wheel (23); the magnets (44) are respectively mounted at the bottom ends of the limiting plate (48) and the fixing plate (41), and the magnets (44) adsorb the first electromagnet (43) and the second electromagnet (45);

a power supply mechanism (6), wherein the power supply mechanism (6) is installed on the side walls of the first guide rail (21) and the second guide rail (22);

the connecting mechanism (8) is mounted at the joint of the first guide rail (21) and the second guide rail (22);

the driving mechanism (7), the said driving mechanism (7) connects the said link gear (8);

adjustment mechanism (9), adjustment mechanism (9) sliding connection the inside of second guide rail (22), just drive wheel (23) are contradicted adjustment mechanism (9)'s top.

2. The industrial running water and muck disposal method according to claim 1, wherein the mixing pan (3) comprises a main body (31), a base (32), a hydraulic cylinder (33) and a blanking plate (34), and the driving wheel (23) and the first variable frequency motor (24) are mounted at the bottom end of the base (32); the bottom end of the main body (31) is symmetrically provided with the base (32); the bottom end of the main body (31) is symmetrically and rotatably connected with the blanking plate (34), and two ends of the hydraulic cylinder (33) are respectively and rotatably connected with the blanking plate (34) and the side wall of the base (32).

3. The industrial running water and residue soil disposal method according to claim 2, wherein the power supply mechanism (6) comprises a connecting rod (61), a second connecting plate (62), steel balls (63), a bracket (64) and a metal plate (65), the second connecting plate (62) is respectively installed on the side walls of the first guide rail (21) and the second guide rail (22), and the metal plate (65) is symmetrically installed inside the second connecting plate (62); the bottom of main part (31) is installed connecting rod (61), the one end installation of connecting rod (61) support (64), the lateral wall roll connection of support (64) steel ball (63), steel ball (63) sliding connection the lateral wall of metal sheet (65), just steel ball (63) with electric connection between first inverter motor (24).

4. The industrial running water and residue soil disposal method according to claim 3, wherein the connecting mechanism (8) comprises a first metal sheet (81), a second metal sheet (82), a fixed shaft (83), a second gear (84) and a toothed plate (85), the first metal sheet (81) and the second metal sheet (82) are rotatably connected to the inside of the second connecting plate (62) at the side wall of the first guide rail (21), one ends of the first metal sheet (81) and the second metal sheet (82) are respectively rotatably connected to the fixed shaft (83), one end of the fixed shaft (83) is fixedly connected to the second gear (84), and the second gear (84) and the fixed shaft (83) are rotatably connected to the inside of the first guide rail (21); the inner portion of the first guide rail (21) is slidably connected with the toothed plate (85), and the toothed plate (85) engages the second gear (84).

5. The industrial running water and residue soil disposal method according to claim 4, wherein the driving mechanism (7) comprises a compression rod (71), a sliding rod (72), a sliding groove (73), a rubber rod (74), a lifting plate (75), a limiting block (76) and a first spring (77), the sliding groove (73) is arranged on the side wall of the first guide rail (21), the compression rod (71) and the sliding rod (72) are rotatably connected to the inside of the sliding groove (73), the compression rod (71) is fixedly connected to the side wall of the second guide rail (22), and the compression rod (71) is slidably connected to the side wall of the sliding rod (72); the rubber rod (74) with elasticity is connected to the inner part of the first guide rail (21) in a sliding mode, and the rubber rod (74) with the arc-shaped side wall props against the side wall of the sliding rod (72); the lifting plate (75) is connected to the inside of the first guide rail (21) in a sliding manner, two ends of the lifting plate (75) respectively abut against the rubber rod (74) and the limiting block (76), and the limiting block (76) is fixedly connected to the inside of the first guide rail (21); the top end of the lifting plate (75) is fixedly connected with the toothed plate (85), the first spring (77) is symmetrically arranged in the first guide rail (21), and the first spring (77) abuts against the top surface of the lifting plate (75).

6. The industrial running water and residue soil disposal method according to claim 1, wherein the adjusting mechanism (9) comprises a projection (91), a metal rod (92), a metal block (93) and a second spring (94), the inner part of the second guide rail (22) is slidably connected with the projection (91) with the T-shaped side wall, the second spring (94) is installed in the inner part of the second guide rail (22), and the second spring (94) abuts against the bottom end of the projection (91); the inside symmetry installation of second guide rail (22) metal block (93), the both ends symmetry installation respectively of lug (91) metal pole (92), metal pole (92) are contradicted metal block (93), just metal block (93) with metal pole (92) electric connection first electro-magnet (43) with second electro-magnet (45).

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