CN111452414A - Scrap iron recycling and processing block forming equipment - Google Patents

Abstract

The invention relates to the field of mechanical equipment, in particular to scrap iron recycling and processing equipment which can generate a large amount of scrap iron in mechanical production, can pollute the environment and cause waste by random treatment, can be made into building materials after being mixed with sand and stone water, is applied to various fields, and solves the problems on the basis of the reasons. And the pressing plate is used for snapping and conveying the materials to a disc to be transported out through a track, so that the pressing is completed.

Description

Scrap iron recycling and processing block forming equipment

Technical Field

The invention relates to the field of mechanical equipment, in particular to equipment for recycling and processing scrap iron into blocks.

Background

A large amount of scrap iron can be generated in mechanical production, the environment can be polluted and the waste can be caused by random treatment, the scrap iron and the sand-gravel water can be made into building materials after being mixed, and the building materials can be applied to various fields.

Disclosure of Invention

The invention aims to provide a device for recycling and processing scrap iron into blocks, which can crush the scrap iron into powder, separate the scrap iron from impurities, mix the scrap iron with sand and gravel water, fully stir and press the mixture into blocks, and automatically convey the blocks.

The purpose of the invention is realized by the following technical scheme:

the utility model provides an iron fillings recycle processing blocking equipment, is including flattening the assembly, cutting up the assembly, stirring assembly and carrying the assembly, cut up the assembly, stir the assembly, carry the assembly all to be connected with flattening the assembly, cut up the assembly and be connected with stirring assembly, stir the assembly and carry the assembly to be connected.

As a further optimization of the technical scheme, the scrap iron recycling and processing equipment comprises a flattening assembly, wherein the flattening assembly comprises a hopper, a flattening shell, a supporting column, a bottom plate, a discharge port, a cross beam, a motor I support, a motor I shaft, a turning gear, a transmission belt wheel I, a roller shaft, a belt I, an output shaft, a compression roller I, a compression roller II, a guide plate and a guide inclined plane, the hopper is connected with the flattening shell to find a dragon formula, the flattening shell is connected with the supporting column, the supporting column is connected with the bottom plate, the flattening shell is connected with the discharge port and the cross beam, the discharge port is connected with the cross beam, the motor I is connected with the motor I support, the motor I support is connected with the flattening shell, the motor I shaft is rotatably connected with the flattening shell, the motor I shaft is connected with the turning gear, the turning gears are eight, and every, six change gear all is connected with the roller, a change gear is connected with the output shaft, driving pulley I is equipped with six, per two I belts of a set of driving pulley are connected with belt I, I axle of motor is connected with a driving pulley I, four rollers are connected with four driving pulley I, the output shaft is connected with a driving pulley I, the roller, the output shaft all rotates with flattening shell and is connected, I axle of motor, two rollers, the output shaft is connected with four compression roller I, four rollers are connected with four compression roller I, adjacent compression roller I equals with II sizes of compression roller, the clearance of four compression roller I and compression roller II diminishes in proper order, deflector and two direction inclined planes all are connected with flattening the shell.

As a further optimization of the technical scheme, the scrap iron recycling and processing equipment comprises a cutting assembly, wherein the cutting assembly comprises a driving belt wheel II, a belt II, a driving belt wheel III shaft, a speed change shell, an input bevel gear I, an input bevel gear II shaft, a sliding chute, a sliding gear I, a spherical groove sliding barrel, a sliding gear II, a speed change handle shaft, an operating gear, an operating rack, a sliding rod, a shifting fork, a shifting ball, a speed change gear I shaft, a speed change gear II, an output bevel gear I, an output bevel gear II shaft, an output belt wheel I, an output belt wheel II, a disc, a shifting column, a connecting rod I, a connecting rod II, a supporting connecting rod, a cutting knife supporting rod, a cutting knife, a magnetic roller driving gear I, a magnetic roller driving gear II, a magnetic roller shaft, Scraper blade, debris collecting chamber, the sliding door, iron fillings transfer passage I and intermediate connection axle, motor I axle is connected with driving pulley II, driving pulley III is connected through belt II, driving pulley III is connected with driving pulley III axle, driving pulley III axle is connected with speed change shell rotation, speed change shell is connected with flattening shell, driving pulley III axle is connected with input bevel gear I, input bevel gear I is meshing with input bevel gear II and is linked, input bevel gear II is connected with input bevel gear II axle, input bevel gear II axle is connected with speed change shell rotation, the spout is located input bevel gear II axle, sliding gear I, the ball groove slide cartridge, sliding gear II all is connected with the spout sliding, sliding gear I is connected with the ball groove slide cartridge, the ball groove slide cartridge is connected with sliding gear II, the gear lever is connected with the speed change axle, the speed change handle axle is connected with speed change shell rotation, the variable speed handle shaft is connected with an operating gear, the operating gear is meshed and linked with an operating rack, the operating rack is connected with a sliding rod, the sliding rod is connected with a shifting fork, the shifting fork is connected with two shifting balls, the shifting balls are slidably connected with a ball groove sliding barrel, a first speed gear and a second speed gear are both connected with a first speed gear shaft, the first speed gear shaft is rotatably connected with a variable speed shell, the first speed gear shaft is connected with an output bevel gear I, the output bevel gear I is meshed and linked with a second output bevel gear, the second output bevel gear is connected with a second output bevel gear shaft, the second output bevel gear shaft is rotatably connected with a flattening shell, the second output bevel gear shaft is connected with a first output belt wheel, the first output belt wheel and the second output belt wheel are connected through an output belt, the second output belt wheel is connected with an intermediate connecting shaft, the intermediate connecting, the disc, dial the post, connecting rod I, connecting rod II, the supporting link, the cutting off cutter bracing piece all is equipped with two and the both sides are each other symmetry, the disc is connected with dialling the post, dial the post and be connected with connecting rod I rotation, connecting rod I is articulated with connecting rod II, connecting rod II is articulated with the supporting link, the supporting link is articulated with flattening shell, connecting rod II is articulated with the cutting off cutter bracing piece, two cutting off cutter bracing pieces are all connected with the cutting off cutter, the cutting off cutter is connected with the crossbeam slip, magnetic roll drive gear I is connected with the output shaft, magnetic roll drive gear I is linked with magnetic roll drive gear II meshing, magnetic roll drive gear II is connected with the magnetic roll axle, the magnetic roll axle is connected with the magnetic roll, the magnetic roll axle is connected with two magnetic roll axle lugs rotation, two magnetic roll axle lugs are all connected with the bottom plate, the scraper blade is connected with two magnetic roll axle lugs, magnetic roll axle, Iron fillings transfer passage I all is connected with the bottom plate, and the sliding door is articulated mutually with debris collecting chamber.

As a further optimization of the technical scheme, the scrap iron recycling and processing equipment comprises a scrap iron conveying channel II, a stirring barrel, a lifting operating handle, an operating handle shaft, a lifting system belt wheel I, a lifting system belt wheel II, a threaded shaft bracket, a lifting scrap iron supporting plate, a supporting plate sliding rail, a motor II bracket, a motor II shaft, an end cover, an inner gear ring, a supporting frame, a sun gear, a planetary system bracket, a planetary gear shaft, a spiral blade, a fan blade, a sliding handle, a handle sliding chute, an outlet baffle, a pressing channel, a pressing cutter, a tension spring and a supporting plate, wherein the scrap iron conveying channel I is connected with the scrap iron conveying channel II, the scrap iron conveying channel II is connected with the stirring barrel, the lifting operating handle is connected with the operating handle shaft, and the operating handle shaft is rotatably connected with a bottom plate, the operating handle shaft is connected with a lifting system belt wheel I, the lifting system belt wheel II is connected through a lifting system belt, the lifting system belt wheel II is connected with a threaded shaft, the threaded shaft is rotationally connected with a threaded shaft bracket, the threaded shaft bracket is connected with a stirring barrel, the threaded shaft is in threaded connection with a lifting scrap iron supporting plate, the lifting scrap iron supporting plate is in sliding connection with two supporting plate sliding rails, the two supporting plate sliding rails are connected with the stirring barrel, a motor II is connected with a motor II bracket, the motor II bracket is connected with an end cover, the end cover is connected with an inner gear ring, the inner gear ring is connected with a supporting frame, the supporting frame is connected with the stirring barrel, the motor II is connected with the motor II shaft, the motor II shaft is rotationally connected with the end cover, the motor II shaft is connected with a sun gear, two planetary gear are connected with two planetary gear axle, two planetary gear axles, II axles of motor all are connected with planetary system support rotation, two planetary gear axles are connected with two spiral leaves, II axles of motor are connected with the flabellum, sliding handle and handle spout sliding connection, the handle spout is located the agitator, sliding handle is connected with the export baffle, the agitator lower part is equipped with the export, the suppression passageway is connected with the export of agitator, two compress tightly the cutter and all with suppression passageway sliding connection, two extension spring both ends respectively with two compress tightly the cutter, the suppression passageway both sides are connected, two extension springs all are in the normality, the layer board is connected with the suppression passageway.

As a further optimization of the technical scheme, the scrap iron recycling and processing equipment comprises a conveying system belt, conveying system belt wheels, a central shaft, a conveying disc, a rotating frame, threaded cylinders, shifting plates and a conveying track, wherein the supporting plate is connected with the conveying track, the two conveying system belt wheels are connected through the conveying system belt, the two conveying system belt wheels are respectively connected with a motor II shaft and the central shaft, the central shaft is rotatably connected with a bottom plate, the central shaft is connected with the conveying disc and the rotating frame, the rotating frame is connected with the four threaded cylinders, the four threaded cylinders are respectively in threaded connection with the four shifting plates, and the conveying track is not in contact with the conveying disc.

The scrap iron recycling and processing block forming equipment has the beneficial effects that:

scrap iron has the iron wire form that residue form and turning or other processing formed, begin work, flatten these iron wire form scrap irons together and reduce the space and occupy, then cut into the end with the scrap iron after flattening, the frequency that the chopper cut up is adjustable, just so can reach the effect of control scrap iron size through changing the frequency, scrap iron handles and impurity separation through the magnetic roller, be carried to in the agitator and fully stir with grit water, open the baffle after the stirring is accomplished, under the effect of gravity and flabellum centrifugal force, the mixture is suppressed the piece through pressing passageway and is discharged the agitator, and dial the board and break, carry to the disc on through rail transport go out, accomplish the suppression, dial the board and reduce the frequency of stirring through dismantling, thereby change the length of suppressing the piece.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

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

fig. 2 is a first schematic view of the configuration of the collapsing assembly 1 according to the invention;

fig. 3 is a schematic view of the structure of the flattening assembly 1 of the present invention;

fig. 4 is a schematic view in partial cross-section of a collapsing assembly 1 according to the invention;

fig. 5 is an enlarged, fragmentary view of the crush box 1 of the present invention;

FIG. 6 is a first schematic view of the shredding assembly 2 of the present invention;

FIG. 7 is a second schematic structural view of the shredding assembly 2 of the present invention;

FIG. 8 is a third schematic structural view of the shredding assembly 2 of the present invention;

FIG. 9 is a fourth schematic structural view of the shredding assembly 2 of the present invention;

FIG. 10 is a schematic view of a shredding assembly 2 of the present invention in partial cross-section one;

FIG. 11 is a fifth schematic structural view of the shredding assembly 2 of the present invention;

FIG. 12 is a sixth schematic view of the shredding assembly 2 of the present invention;

FIG. 13 is an enlarged partial schematic view of the shredding assembly 2 of the present invention;

FIG. 14 is a seventh schematic structural view of the shredding assembly 2 of the present invention;

FIG. 15 is a schematic view of the shredding assembly 2 of the present invention in partial cross-section two;

FIG. 16 is a schematic view eight of the shredding assembly 2 of the present invention;

FIG. 17 is a first schematic structural view of the stirring assembly 3 of the present invention;

FIG. 18 is a second schematic structural view of the stirring assembly 3 of the present invention;

FIG. 19 is a schematic partial cross-sectional view of the stirring assembly 3 of the present invention;

FIG. 20 is a third schematic structural view of the stirring assembly 3 of the present invention;

FIG. 21 is an enlarged partial schematic view of the stirring assembly 3 of the present invention;

FIG. 22 is a fourth schematic structural view of the stirring assembly 3 of the present invention;

FIG. 23 is a schematic structural view of the stirring assembly 3 of the present invention;

fig. 24 is a schematic view of the structure of the conveying assembly 4 of the present invention.

In the figure: flattening the combined body 1; 1-1 of a hopper; flattening the outer shell 1-2; 1-3 of a support column; 1-4 of a bottom plate; 1-5 of a discharge port; 1-6 of a cross beam; 1-7 of a motor I; 1-8 of a bracket of a motor I; 1-9 of a shaft of a motor I; 1-10 of a change gear; transmission belt wheels I1-11; 1-12 parts of roll shafts; 1-13 parts of a belt; output shafts 1 to 14; 1-15 parts of a press roll I; pressing rollers II 1-16; guide plates 1-17 and guide slopes 1-18; a shredding assembly 2; a transmission belt pulley II 2-1; a belt II 2-2; a driving belt wheel III 2-3; 2-4 of a driving belt wheel III; 2-5 of a speed change shell; input bevel gears I2-6; input bevel gears II 2-7; 2-8 of an input bevel gear II shaft; 2-9 of a chute; 2-10 parts of a sliding gear I; 2-11 parts of a ball groove sliding cylinder; 2-12 parts of a sliding gear; 2-13 of a speed changing handle; a shift handle shaft 2-14; operating gears 2-15; operating racks 2-16; 2-17 of a slide rod; 2-18 of a shifting fork; 2-19 of ball poking; 2-20 of a speed change gear; 2-21 of a speed change gear I shaft; speed change gears II 2-22; output bevel gears I2-23; output bevel gears II 2-24; 2-25 of an output bevel gear II shaft; an output belt wheel I2-26; output belts 2-27; an output belt wheel II 2-28; 2-29 of round plate; 2-30 of a shifting column; 2-31 parts of a connecting rod; 2-32 of a connecting rod; support links 2-33; cutting knife supporting rods 2-34; 2-35 parts of a cutting knife; magnetic roller transmission gears I2-36; magnetic roller transmission gears II 2-37; 2-38 of magnetic roller shaft; 2-39 parts of magnetic roller; 2-40 of magnetic roll shaft support lugs; 2-41 parts of a scraper; 2-42 parts of a sundries collecting chamber; 2-43 of sliding door; the scrap iron conveying channel I2-44; the middle connecting shaft is 2-45; a stirring assembly 3; the scrap iron conveying channel II 3-1; 3-2 of a stirring barrel; 3-3 of a lifting operation handle; operating the handle shaft 3-4; a lifting system belt wheel I3-5; 3-6 of a lifting system belt; a lifting system belt wheel II 3-7; 3-8 parts of a threaded shaft; 3-9 parts of a threaded shaft support; 3-10 of a lifting scrap iron supporting plate; 3-11 of a support plate slide rail; 3-12 of a motor II; 3-13 of a bracket of a motor II; 3-14 of a motor II shaft; 3-15 parts of an end cover; 3-16 parts of inner gear ring; 3-17 of a support frame; sun gears 3-18; a planetary system carrier 3-19; 3-20 parts of a planetary gear; planetary gear shafts 3 to 21; 3-22 parts of spiral leaves; fan blades 3-23; 3-24 of a sliding handle; handle chutes 3-25; outlet baffles 3-26; pressing channels 3-27; 3-28 parts of a pressing cutter; 3-29 of a tension spring; 3-30 parts of a supporting plate; the conveying assembly 4; a conveying system belt 4-1; a conveying system belt wheel 4-2; 4-3 of a central shaft; 4-4 of a conveying disc; 4-5 of a rotating frame; 4-6 of a threaded cylinder; 4-7 of a shifting plate; the conveying tracks 4-8.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, and an apparatus for recycling and processing scrap iron into blocks includes a flattening assembly 1, a shredding assembly 2, a stirring assembly 3, and a conveying assembly 4, wherein the shredding assembly 2, the stirring assembly 3, and the conveying assembly 4 are all connected to the flattening assembly 1, the shredding assembly 2 is connected to the stirring assembly 3, and the stirring assembly 3 is connected to the conveying assembly 4.

The second embodiment is as follows:

the embodiment is described below by referring to fig. 1, and the embodiment is further described, wherein the flattening assembly 1 comprises a hopper 1-1, a flattening shell 1-2, support columns 1-3, a bottom plate 1-4, a discharge port 1-5, cross beams 1-6, motors I1-7, motor I supports 1-8, motors I shafts 1-9, direction-changing gears 1-10, transmission pulleys I1-11, roller shafts 1-12, belts I1-13, output shafts 1-14, press rollers I1-15, press rollers II 1-16, guide plates 1-17 and guide slopes 1-18, the hopper 1-1 and the flattening shell 1-2 are dragon-seeking tables, the flattening shell 1-2 is connected with the support columns 1-3, the support columns 1-3 are connected with the bottom plate 1-4, the flattening shell 1-2 is connected with the discharge port 1-5 and the cross beam 1-6, the discharge port 1-5 is connected with the cross beam 1-6, the motor I1-7 is connected with the motor I bracket 1-8, the motor I bracket 1-8 is connected with the flattening shell 1-2, the motor I1-7 is connected with the motor I shaft 1-9, the motor I shaft 1-9 is rotatably connected with the flattening shell 1-2, the motor I shaft 1-9 is connected with the change gear 1-10, the change gear 1-10 is provided with eight change gears 1-10, each two change gears 1-10 are meshed and linked, the six change gears 1-10 are connected with the roll shaft 1-12, one change gear 1-10 is connected with the output shaft 1-14, and the transmission belt wheels I1-11 are provided with six, every two driving belt wheels I1-11 in a group are connected with belts I1-13, a motor I shaft 1-9 is connected with one driving belt wheel I1-11, four roll shafts 1-12 are connected with four driving belt wheels I1-11, an output shaft 1-14 is connected with one driving belt wheel I1-11, the roll shafts 1-12 and the output shaft 1-14 are rotatably connected with a flattening shell 1-2, the motor I shaft 1-9, the two roll shafts 1-12 and the output shaft 1-14 are connected with four press rolls I1-15, the four roll shafts 1-12 are connected with the four press rolls I1-15, the adjacent press rolls I1-15 and the press rolls II 1-16 have the same size, and the gaps between the four groups of press rolls I1-15 and the press rolls II 1-16 are sequentially reduced, the guide plate 1-17 and the two guide inclined planes 1-18 are connected with the flattening shell 1-2 and can flatten the iron chips into thin sheets.

The third concrete implementation mode:

referring to FIG. 1, the present embodiment will be described in detail, and the shredded assembly 2 includes a driving pulley II 2-1, a belt II 2-2, a driving pulley III 2-3, a driving pulley III shaft 2-4, a speed change housing 2-5, an input bevel gear I2-6, an input bevel gear II 2-7, an input bevel gear II shaft 2-8, a chute 2-9, a sliding gear I2-10, a ball slot sliding cylinder 2-11, a sliding gear II 2-12, a shift lever 2-13, a shift lever shaft 2-14, an operating gear 2-15, an operating rack 2-16, a sliding rod 2-17, a shift fork 2-18, a shifting ball 2-19, a shift gear I2-20, a shift gear I shaft 2-21, a shifting lever shaft 2-19, a shifting ball 2-19, a shifting gear I2-21, Speed change gears II 2-22, output bevel gears I2-23, output bevel gears II 2-24, output bevel gear II shafts 2-25, output belt wheels I2-26, output belts 2-27, output belt wheels II 2-28, discs 2-29, shifting columns 2-30, connecting rods I2-31, connecting rods II 2-32, supporting connecting rods 2-33, cutting knife supporting rods 2-34, cutting knives 2-35, magnetic roller transmission gears I2-36, magnetic roller transmission gears II 2-37, magnetic roller shafts 2-38, magnetic rollers 2-39, magnetic roller shaft supporting lugs 2-40, scraping plates 2-41, sundries collecting chambers 2-42, sliding doors 2-43, scrap iron conveying channels I2-44 and intermediate connecting shafts 2-45, motor I shafts 1-9 are connected with the transmission belt wheels II 2-1, the driving belt wheel II 2-1 and the driving belt wheel III 2-3 are connected through a belt II 2-2, the driving belt wheel III 2-3 is connected with a driving belt wheel III shaft 2-4, the driving belt wheel III shaft 2-4 is rotatably connected with a speed change shell 2-5, the speed change shell 2-5 is connected with a flattening shell 1-2, the driving belt wheel III shaft 2-4 is connected with an input bevel gear I2-6, the input bevel gear I2-6 is meshed and linked with an input bevel gear II 2-7, the input bevel gear II 2-7 is connected with an input bevel gear II shaft 2-8, the input bevel gear II shaft 2-8 is rotatably connected with a speed change shell 2-5, the chute 2-9 is positioned on the input bevel gear II shaft 2-8, the sliding gear I2-10, the spherical groove sliding barrel 2-11, The sliding gears II 2-12 are all connected with the sliding chutes 2-9 in a sliding manner, the sliding gears I2-10 are connected with the ball groove sliding cylinders 2-11, the ball groove sliding cylinders 2-11 are connected with the sliding gears II 2-12, the speed changing handles 2-13 are connected with the speed changing handle shafts 2-14, the speed changing handle shafts 2-14 are rotatably connected with the speed changing shell 2-5, the speed changing handle shafts 2-14 are connected with the operating gears 2-15, the operating gears 2-15 are meshed and linked with the operating racks 2-16, the operating racks 2-16 are connected with the sliding rods 2-17, the sliding rods 2-17 are connected with the shifting forks 2-18, the shifting forks 2-18 are connected with the two shifting balls 2-19, the shifting balls 2-19 are connected with the ball groove sliding cylinders 2-11 in a sliding manner, and the speed changing gears I2-20, The speed change gears II 2-22 are all connected with a speed change gear I shaft 2-21, the speed change gear I shaft 2-21 is rotatably connected with a speed change shell 2-5, the speed change gear I shaft 2-21 is connected with an output bevel gear I2-23, the output bevel gear I2-23 is meshed and linked with an output bevel gear II 2-24, the output bevel gear II 2-24 is connected with an output bevel gear II shaft 2-25, the output bevel gear II shaft 2-25 is rotatably connected with a flattening shell 1-2, the output bevel gear II shaft 2-25 is connected with an output belt wheel I2-26, the output belt wheel I2-26 and the output belt wheel II 2-28 are connected through an output belt 2-27, the output belt wheel II 2-28 is connected with an intermediate connecting shaft 2-45, the intermediate connecting shaft 2-45 is rotatably connected with the flattening shell 1-2, two ends of an intermediate connecting shaft 2-45 are connected with two disks 2-29, the disks 2-29, a shifting column 2-30, a connecting rod I2-31, a connecting rod II 2-32, a supporting connecting rod 2-33 and a cutting knife supporting rod 2-34 are all provided with two symmetrical sides, the disks 2-29 are connected with the shifting column 2-30, the shifting column 2-30 is rotatably connected with the connecting rod I2-31, the connecting rod I2-31 is hinged with the connecting rod II 2-32, the connecting rod II 2-32 is hinged with the supporting connecting rod 2-33, the supporting connecting rod 2-33 is hinged with a flattening shell 1-2, the connecting rod II 2-32 is hinged with the cutting knife supporting rod 2-34, the two cutting knife supporting rods 2-34 are both connected with cutting knives 2-35, the cutting knives 2-35 are in sliding connection with cross beams 1-6, the magnetic roller transmission gears I2-36 are connected with the output shafts 1-14, the magnetic roller transmission gears I2-36 are meshed and linked with the magnetic roller transmission gears II 2-37, the magnetic roller transmission gears II 2-37 are connected with the magnetic roller shafts 2-38, the magnetic roller shafts 2-38 are connected with the magnetic rollers 2-39, the magnetic roller shafts 2-38 are rotatably connected with two magnetic roller shaft support lugs 2-40, the two magnetic roller shaft support lugs 2-40 are both connected with the bottom plate 1-4, the scraping plates 2-41 are connected with the two magnetic roller shaft support lugs 2-40, the magnetic roller shaft support lugs 2-40 are in contact with the magnetic rollers 2-39, the sundries collecting chamber 2-42 and the scrap iron conveying channel I2-44 are both connected with the bottom plate 1-4, the sliding door 2-43 is hinged with the sundries collecting chamber 2-42 to crush the flattened sheets into powder, separating the scrap iron from the impurities.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, and the embodiment is further described, wherein the stirring assembly 3 comprises a scrap iron conveying channel II 3-1, a stirring barrel 3-2, a lifting operation handle 3-3, an operation handle shaft 3-4, a lifting system belt pulley I3-5, a lifting system belt 3-6, a lifting system belt pulley II 3-7, a threaded shaft 3-8, a threaded shaft bracket 3-9, a lifting scrap iron supporting plate 3-10, a supporting plate sliding rail 3-11, a motor II 3-12, a motor II bracket 3-13, a motor II shaft 3-14, an end cover 3-15, an inner gear ring 3-16, a supporting bracket 3-17, a sun gear 3-18, a planetary system bracket 3-19, a planetary gear 3-20, a planetary gear 3-19, a planetary gear 3-20, 3-21 parts of planetary gear shafts, 3-22 parts of spiral blades, 3-23 parts of fan blades, 3-24 parts of sliding handles, 3-25 parts of handle chutes, 3-26 parts of outlet baffles, 3-27 parts of pressing channels, 3-28 parts of pressing cutters, 3-29 parts of tension springs and 3-30 parts of supporting plates, wherein the iron scrap conveying channels I2-44 are connected with the iron scrap conveying channels II 3-1, the iron scrap conveying channels II 3-1 are connected with the stirring barrel 3-2, the lifting operating handles 3-3 are connected with the operating handle shafts 3-4, the operating handle shafts 3-4 are rotatably connected with the bottom plate 1-4, the operating handle shafts 3-4 are connected with the lifting system belt pulleys I3-5, the lifting system belt pulleys I3-5 and the lifting system belt pulleys II 3-7 are connected through lifting system belts 3-6, the lifting system belt wheel II 3-7 is connected with a threaded shaft 3-8, the threaded shaft 3-8 is rotationally connected with a threaded shaft support 3-9, the threaded shaft support 3-9 is connected with a stirring barrel 3-2, the threaded shaft 3-8 is in threaded connection with a lifting iron scrap support plate 3-10, the lifting iron scrap support plate 3-10 is in sliding connection with two support plate slide rails 3-11, the two support plate slide rails 3-11 are both connected with the stirring barrel 3-2, the motor II 3-12 is connected with a motor II support 3-13, the motor II support 3-13 is connected with an end cover 3-15, the end cover 3-15 is connected with an inner gear ring 3-16, the inner gear ring 3-16 is connected with a support frame 3-17, the support frame 3-17 is connected with the stirring barrel 3-2, the motor II 3-12 is connected with a motor II shaft 3-14, the motor II shaft 3-14 is rotationally connected with an end cover 3-15, the motor II shaft 3-14 is connected with a sun gear 3-18, the sun gear 3-18 is meshed and linked with two planetary gears 3-20, the two planetary gears 3-20 are meshed and linked with an inner gear ring 3-16, the two planetary gears 3-20 are connected with two planetary gear shafts 3-21, the two planetary gear shafts 3-21 and the motor II shaft 3-14 are rotationally connected with a planetary system bracket 3-19, the two planetary gear shafts 3-21 are connected with two spiral blades 3-22, the motor II shaft 3-14 is connected with a fan blade 3-23, and a sliding handle 3-24 is slidably connected with a handle chute 3-25, the handle chute 3-25 is positioned on the stirring barrel 3-2, the sliding handle 3-24 is connected with the outlet baffle 3-26, the lower part of the stirring barrel 3-2 is provided with an outlet, the pressing channel 3-27 is connected with the outlet of the stirring barrel 3-2, the two pressing cutters 3-28 are both connected with the pressing channel 3-27 in a sliding way, the two ends of the two tension springs 3-29 are respectively connected with the two pressing cutters 3-28 and the two sides of the pressing channel 3-27, the two tension springs 3-29 are both in a normal state, the supporting plate 3-30 is connected with the pressing channel 3-27, and the scrap iron and the sand and the water can be fully stirred and pressed into blocks after being mixed.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1, and the embodiment further describes the first embodiment, the conveying assembly 4 includes a conveying system belt 4-1, a conveying system belt pulley 4-2, a central shaft 4-3, a conveying disc 4-4, a rotating frame 4-5, a threaded cylinder 4-6, a shifting plate 4-7 and a conveying track 4-8, a supporting plate 3-30 is connected with the conveying track 4-8, two conveying system belt pulleys 4-2 are connected with the conveying system belt 4-1, two conveying system belt pulleys 4-2 are respectively connected with a motor ii shaft 3-14 and the central shaft 4-3, the central shaft 4-3 is rotatably connected with the bottom plate 1-4, the central shaft 4-3 is connected with the conveying disc 4-4 and the rotating frame 4-5, the rotating frame 4-5 is connected with four threaded cylinders 4-6, the four threaded cylinders 4-6 are respectively in threaded connection with four shifting plates 4-7, the conveying tracks 4-8 are not in contact with the conveying discs 4-4, and the briquettes are automatically conveyed after being pressed into briquettes.

The invention relates to a device for recycling and processing scrap iron into blocks, which has the working principle that: scrap iron is in a residue shape and an iron wire shape formed by turning or other processing, the scrap iron is put into a hopper, a motor I1-7 is started, the motor I1-7 drives a motor I shaft 1-9 to rotate, the motor I shaft 1-9 drives a change gear 1-10 to rotate, the change gear 1-10 drives an adjacent change gear 1-10 to rotate, the adjacent change gear 1-10 drives a roller shaft 1-12 to rotate, the motor I shaft 1-9 and the roller shaft 1-12 respectively drive adjacent compression rollers I1-15 and compression rollers II 1-16 to rotate oppositely, the scrap iron in the hopper 1-1 is flattened and conveyed to the next set of compression rollers I1-15 and compression rollers II 1-16, the motor I shaft 1-9 drives a transmission belt wheel I1-11 to rotate, the transmission belt wheel I1-11 drives a lower transmission belt wheel I1-11 to rotate through a belt I1-13, thus, the power is transmitted to the next two roll shafts 1-12, similarly, the compression rollers I1-15 and the compression rollers II 1-16 driven by the two roll shafts 1-12 rotate oppositely, similarly, the next two compression rollers I1-15 and the compression rollers II 1-16 rotate oppositely, the four compression rollers I1-15 and the compression rollers II 1-16 rotate oppositely to crush and convey scrap iron, the clearance between the four compression rollers I1-15 and the compression rollers II 1-16 is reduced sequentially, the scrap iron is crushed to be thinnest by the last compression roller I1-15 and the compression rollers II 1-16 and then discharged through the discharge port 1-5, the motor I shaft 1-9 drives the transmission belt pulley II 2-1 to rotate, the transmission belt pulley II 2-1 drives the transmission belt pulley III 2-3 to rotate through the belt II 2-2, the transmission belt pulley III 2-3 drives the transmission belt pulley III shaft 2-4 to rotate, the shaft 2-4 of the driving belt wheel III drives the input bevel gear I2-6 to rotate, the input bevel gear I2-6 drives the input bevel gear II 2-7 to rotate, the input bevel gear II 2-7 drives the input bevel gear II shaft 2-8 to rotate, the input bevel gear II shaft 2-8 drives the sliding gear I2-10, the spherical groove sliding cylinder 2-11 and the sliding gear II 2-12 to rotate through the chute 2-9, the speed change handle 2-13 is rotated, the speed change handle 2-13 drives the speed change handle shaft 2-14 to rotate, the speed change handle shaft 2-14 drives the operating gear 2-15 to rotate, the operating gear 2-15 drives the sliding rod 2-17 to slide left and right in the speed change shell 2-5 through the operating rack 2-16, the sliding rod 2-17 cannot rotate due to radial limitation of the speed change shell 2-5, the sliding rod 2-17 drives the shifting fork 2-18 to slide left and right, the shifting fork 2-18 drives the ball groove sliding cylinder 2-11 to slide left and right through two shifting balls 2-19, the ball groove sliding cylinder 2-11 drives the sliding gear I2-10 and the sliding gear II 2-12 to slide left and right, the transmission ratio is changed by rotating the speed changing handle 2-13 to control the sliding gear I2-10 to be meshed with the speed changing gear I2-20 or the sliding gear II 2-12 to be meshed with the speed changing gear II 2-22 to change the rotating speed of the shaft I2-21 of the speed changing gear, the shaft I2-21 of the speed changing gear drives the output bevel gear I2-23 to rotate, the output bevel gear I2-23 drives the output bevel gear II 2-24 to rotate, the output bevel gear II 2-24 drives the shaft II 2-25 of the output bevel gear to rotate, the output bevel gear II shaft 2-25 drives the output belt wheel I2-26 to rotate, the output belt wheel I2-26 drives the output belt wheel II 2-28 to rotate through the output belt 2-27, the output belt wheel II 2-28 drives the intermediate connecting shaft 2-45 to rotate, the intermediate connecting shaft 2-45 drives the two disks 2-29 to rotate, the disks 2-29 drive the shifting post 2-30 to rotate, the shifting post 2-30 drives one end of the connecting rod I2-31 to do circular motion, the other end of the connecting rod I2-31 drives the connecting rod II 2-32 to do up-and-down reciprocating swing with the supporting connecting rod 2-33 as a fulcrum, the disks 2-29, the shifting post 2-30, the connecting rod I2-31, the connecting rod II 2-32, the supporting connecting rod 2-33 and the cutting knife supporting rod 2-34 are provided with two sides, two connecting rods II 2-32 drive cutting knives 2-35 to slide up and down in a reciprocating manner in a cross beam 1-6 through two cutting knife supporting rods 2-34, the cutting knives 2-35 slide up and down in a reciprocating manner to cut scrap iron sheets discharged from a discharge port 1-5, the vertical sliding frequency of the cutting knives 2-35 is changed by changing the rotating speed of a shaft 2-21 of a speed change gear I, so that the cutting degree of the scrap iron sheets is changed, the crushed iron sheets are discharged from the discharge port 1-5 to be in contact with a magnetic roller 2-39 and adsorbed by the magnetic roller 2-39, impurities cannot fall into an impurity collecting chamber 2-42 to be cleaned by adsorption, a sliding door 2-43 is opened during cleaning, an output shaft 1-14 drives a magnetic roller transmission gear I2-36 to rotate, the magnetic roller transmission gear I2-36 drives a magnetic roller transmission gear II 2-37 to rotate, the magnetic roller transmission gears II 2-37 drive the magnetic roller shafts 2-38 to rotate, the magnetic roller shafts 2-38 drive the magnetic rollers 2-39 to rotate, scrap iron adsorbed by the magnetic rollers 2-39 is scraped by the scraping plates 2-41 to fall into the scrap iron conveying channels I2-44, falls onto the lifting scrap iron supporting plates 3-10 through the inner inclined surfaces of the conveying channels I2-44 and the scrap iron conveying channels II 3-1, when the lifting scrap iron supporting plates 3-10 are full of scrap iron, the motors I1-7 are turned off, the flattening assembly 1 and the chopping assembly 2 are not in work, the lifting operating handles 3-3 are shaken, the lifting operating handles 3-3 drive the operating handle shafts 3-4 to rotate, the operating handle shafts 3-4 drive the lifting system belt pulleys I3-5 to rotate, the lifting system belt pulleys I3-5 drive the lifting system belt pulleys II 3-7 to rotate through the lifting system belts 3-6, the lifting system belt wheel II 3-7 drives the threaded shaft 3-8 to rotate, the threaded shaft 3-8 is axially limited by the threaded shaft support 3-9, the threaded shaft 3-8 drives the lifting scrap iron support plate 3-10 to lift upwards along the support plate slide rail 3-11 through threads, after the lifting scrap iron support plate is lifted to the top, gravel water is added at an inlet formed by the support frame 3-17, the motor II 3-12 is started, the motor II 3-12 drives the motor II shaft 3-14 to rotate, the motor II shaft 3-14 drives the sun gear 3-18 to rotate, the sun gear drives the two planetary gears 3-20 to rotate in the internal gear ring 3-16 and simultaneously revolve around the sun gear 3-18, the two planetary gears 3-20 drive the two planetary gear shafts 3-21 to rotate and simultaneously revolve around the sun gear 3-18, two planetary gear shafts 3-21 drive spiral blades 3-22 to rotate to lift and stir bottom scrap iron uniformly, after the scrap iron and sand water are stirred uniformly, a handle chute 3-25 is slid, the handle chute 3-25 drives an outlet baffle plate 3-26 not to block a pressing channel 3-27, a motor II shaft 3-14 rotates to drive a fan blade 3-23 to rotate to generate centrifugal force, under the action of gravity and centrifugal force, the scrap iron and sand water are discharged from the pressing channel 3-27 to be contacted with a pressing cutter 3-28 inclined surface, the pressing cutter 3-28 drives a tension spring 3-29 to stretch, the tension spring 3-29 drives the pressing cutter 3-28 to generate inward thrust to compact scrap iron blocks, the motor II shaft 3-14 drives a conveying system belt wheel 4-2 to rotate, the conveying system belt wheel 4-2 drives another conveying system belt wheel 4-2 to rotate through a conveying system belt 4-1, the belt wheel 4-2 of the conveying system drives the central shaft 4-3 to rotate, the central shaft 4-3 drives the conveying disc 4-4 and the rotating frame 4-5 to rotate, the rotating frame 4-5 drives the threaded cylinder 4-6 to rotate, the threaded cylinder 4-6 drives the shifting plate 4-7 to rotate, when the shifting plate 4-7 is contacted with the pressed iron filings block, the shifting plate 4-7 shifts and bends the iron filings block to generate cracks, the tension spring 3-29 drives the pressing cutter 3-28 to insert an enlarged crack into the crack, the shifting plate 4-7 shifts and cuts the iron filings block along the enlarged crack, the iron filings block falls on the conveying disc 4-4, the conveying disc 4-4 drives the iron filings block to convey the iron filings block along the conveying track 4-8, the stirring frequency can be reduced by removing the stirring plates 4-7, so that the purpose of increasing the length of the iron scrap blocks is achieved.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. The utility model provides an iron fillings recycle processes blocking equipment, includes and flattens assembly (1), cuts up assembly (2), stirring assembly (3) and carries assembly (4), its characterized in that: the shredding assembly (2), the stirring assembly (3) and the conveying assembly (4) are all connected with the flattening assembly (1), the shredding assembly (2) is connected with the stirring assembly (3), and the stirring assembly (3) is connected with the conveying assembly (4).

2. The scrap iron recycling and processing equipment as claimed in claim 1, wherein the scrap iron recycling and processing equipment comprises: the flattening assembly (1) comprises a hopper (1-1), a flattening shell (1-2), support columns (1-3), a bottom plate (1-4), a discharge hole (1-5), a cross beam (1-6), a motor I (1-7), a motor I support (1-8), a motor I shaft (1-9), a change gear (1-10), a transmission belt wheel I (1-11), a roller shaft (1-12), a belt I (1-13), an output shaft (1-14), a press roller I (1-15), a press roller II (1-16), guide plates (1-17) and guide inclined planes (1-18), the hopper (1-1) and the flattening shell (1-2) seek a dragon formula, and the flattening shell (1-2) is connected with the support columns (1-3), the support column (1-3) is connected with the bottom plate (1-4), the flattening shell (1-2) is connected with the discharge port (1-5) and the cross beam (1-6), the discharge port (1-5) is connected with the cross beam (1-6), the motor I (1-7) is connected with the motor I support (1-8), the motor I support (1-8) is connected with the flattening shell (1-2), the motor I (1-7) is connected with the motor I shaft (1-9), the motor I shaft (1-9) is rotationally connected with the flattening shell (1-2), the motor I shaft (1-9) is connected with the change gears (1-10), eight change gears (1-10) are arranged, and each two change gears (1-10) are meshed and linked, six direction-changing gears (1-10) are connected with roll shafts (1-12), one direction-changing gear (1-10) is connected with an output shaft (1-14), six transmission belt wheels I (1-11) are arranged, every two transmission belt wheels I (1-11) in a group are connected with belts I (1-13), a motor I shaft (1-9) is connected with one transmission belt wheel I (1-11), four roll shafts (1-12) are connected with four transmission belt wheels I (1-11), the output shaft (1-14) is connected with one transmission belt wheel I (1-11), the roll shafts (1-12) and the output shaft (1-14) are rotatably connected with a flattening shell (1-2), the motor I shaft (1-9), the two roll shafts (1-12) and the balance shaft I (1-12), The output shafts (1-14) are connected with four compression rollers I (1-15), four roller shafts (1-12) are connected with the four compression rollers I (1-15), the sizes of the adjacent compression rollers I (1-15) and the compression rollers II (1-16) are equal, gaps between the four groups of compression rollers I (1-15) and the four groups of compression rollers II (1-16) are sequentially reduced, and the guide plates (1-17) and the two guide inclined planes (1-18) are connected with the flattening shell (1-2).

3. The scrap iron recycling and processing equipment as claimed in claim 1, wherein the scrap iron recycling and processing equipment comprises: the chopping assembly (2) comprises a transmission belt wheel II (2-1), a belt II (2-2), a transmission belt wheel III (2-3), a transmission belt wheel III shaft (2-4), a speed change shell (2-5), an input bevel gear I (2-6), an input bevel gear II (2-7), an input bevel gear II shaft (2-8), a sliding groove (2-9), a sliding gear I (2-10), a ball groove sliding cylinder (2-11), a sliding gear II (2-12), a speed change handle (2-13), a speed change handle shaft (2-14), an operating gear (2-15), an operating rack (2-16), a sliding rod (2-17), a shifting fork (2-18), a shifting ball (2-19), a speed change gear I (2-20), A variable speed gear I shaft (2-21), a variable speed gear II (2-22), an output bevel gear I (2-23), an output bevel gear II (2-24), an output bevel gear II shaft (2-25), an output belt wheel I (2-26), an output belt (2-27), an output belt wheel II (2-28), a disc (2-29), a shifting column (2-30), a connecting rod I (2-31), a connecting rod II (2-32), a supporting connecting rod (2-33), a cutting knife supporting rod (2-34), a cutting knife (2-35), a magnetic roller transmission gear I (2-36), a magnetic roller transmission gear II (2-37), a magnetic roller shaft (2-38), a magnetic roller (2-39), a magnetic roller shaft supporting lug (2-40), a scraper (2-41), A sundries collecting chamber (2-42), a sliding door (2-43), an iron scrap conveying channel I (2-44) and an intermediate connecting shaft (2-45), a motor I shaft (1-9) is connected with a driving belt wheel II (2-1), the driving belt wheel II (2-1) and a driving belt wheel III (2-3) are connected through a belt II (2-2), the driving belt wheel III (2-3) is connected with a driving belt wheel III shaft (2-4), the driving belt wheel III shaft (2-4) is rotationally connected with a speed change shell (2-5), the speed change shell (2-5) is connected with a flattening shell (1-2), the driving belt wheel III shaft (2-4) is connected with an input bevel gear I (2-6), the input bevel gear I (2-6) is meshed and linked with the input bevel gear II (2-7), the input bevel gear II (2-7) is connected with an input bevel gear II shaft (2-8), the input bevel gear II shaft (2-8) is rotatably connected with a speed change shell (2-5), a chute (2-9) is positioned on the input bevel gear II shaft (2-8), a sliding gear I (2-10), a ball groove sliding cylinder (2-11) and a sliding gear II (2-12) are respectively and slidably connected with the chute (2-9), the sliding gear I (2-10) is connected with the ball groove sliding cylinder (2-11), the ball groove sliding cylinder (2-11) is connected with the sliding gear II (2-12), a speed change handle (2-13) is connected with a speed change handle shaft (2-14), the speed change handle shaft (2-14) is rotatably connected with the speed change shell (2-5), the speed change handle shaft (2-14) is connected with an operating gear (2-15), the operating gears (2-15) are meshed and linked with the operating racks (2-16), the operating racks (2-16) are connected with sliding rods (2-17), the sliding rods (2-17) are connected with shifting forks (2-18), the shifting forks (2-18) are connected with two shifting balls (2-19), the shifting balls (2-19) are connected with ball groove sliding cylinders (2-11) in a sliding manner, the speed change gears I (2-20) and the speed change gears II (2-22) are connected with a first shaft (2-21) of the speed change gears, the first shaft (2-21) of the speed change gears is rotatably connected with a speed change shell (2-5), the first shaft (2-21) of the speed change gears is connected with an output bevel gear I (2-23), the output bevel gear I (2-23) is meshed and linked with an output bevel gear II (2-24), the output bevel gear II (2-24) is connected with an output bevel gear II shaft (2-25), the output bevel gear II shaft (2-25) is rotatably connected with the flattening shell (1-2), the output bevel gear II shaft (2-25) is connected with an output belt wheel I (2-26), the output belt wheel I (2-26) and the output belt wheel II (2-28) are connected through an output belt (2-27), the output belt wheel II (2-28) is connected with an intermediate connecting shaft (2-45), the intermediate connecting shaft (2-45) is rotatably connected with the flattening shell (1-2), two ends of the intermediate connecting shaft (2-45) are connected with two discs (2-29), the discs (2-29), shifting columns (2-30), a connecting rod I (2-31), a connecting rod II (2-32), Two supporting connecting rods (2-33) and two cutting knife supporting rods (2-34) are arranged and are symmetrical to each other on two sides, discs (2-29) are connected with shifting columns (2-30), the shifting columns (2-30) are rotationally connected with connecting rods I (2-31), the connecting rods I (2-31) are hinged with connecting rods II (2-32), the connecting rods II (2-32) are hinged with the supporting connecting rods (2-33), the supporting connecting rods (2-33) are hinged with a flattening shell (1-2), the connecting rods II (2-32) are hinged with the cutting knife supporting rods (2-34), the two cutting knife supporting rods (2-34) are connected with cutting knives (2-35), the cutting knives (2-35) are connected with cross beams (1-6) in a sliding mode, magnetic roller transmission gears I (2-36) are connected with output shafts (1-14), the magnetic roller transmission gear I (2-36) is meshed and linked with the magnetic roller transmission gear II (2-37), the magnetic roller transmission gear II (2-37) is connected with a magnetic roller shaft (2-38), the magnetic roller shaft (2-38) is connected with a magnetic roller (2-39), the magnetic roller shaft (2-38) is rotatably connected with two magnetic roller shaft support lugs (2-40), the two magnetic roller shaft support lugs (2-40) are both connected with a bottom plate (1-4), a scraping plate (2-41) is connected with the two magnetic roller shaft support lugs (2-40), the magnetic roller shaft support lugs (2-40) are in contact with the magnetic roller (2-39), and a sundries collecting chamber (2-42), the scrap iron conveying channels I (2-44) are connected with the bottom plates (1-4), and the sliding doors (2-43) are hinged with the sundries collecting chambers (2-42).

4. The scrap iron recycling and processing equipment as claimed in claim 1, wherein the scrap iron recycling and processing equipment comprises: the stirring assembly (3) comprises an iron scrap conveying channel II (3-1), a stirring barrel (3-2), a lifting operation handle (3-3), an operation handle shaft (3-4), a lifting system belt wheel I (3-5), a lifting system belt (3-6), a lifting system belt wheel II (3-7), a threaded shaft (3-8), a threaded shaft bracket (3-9), a lifting iron scrap supporting plate (3-10), a supporting plate sliding rail (3-11), a motor II (3-12), a motor II bracket (3-13), a motor II shaft (3-14), an end cover (3-15), an inner gear ring (3-16), a supporting frame (3-17), a sun gear (3-18), a planetary system bracket (3-19), a planetary gear (3-20), Planetary gear shafts (3-21), spiral blades (3-22), fan blades (3-23), sliding handles (3-24), handle chutes (3-25), outlet baffles (3-26), pressing channels (3-27), pressing cutters (3-28), tension springs (3-29) and supporting plates (3-30), scrap iron conveying channels I (2-44) are connected with scrap iron conveying channels II (3-1), the scrap iron conveying channels II (3-1) are connected with a stirring barrel (3-2), lifting operating handles (3-3) are connected with operating handle shafts (3-4), the operating handle shafts (3-4) are rotatably connected with base plates (1-4), the operating handle shafts (3-4) are connected with lifting system belt pulleys I (3-5), the lifting system belt wheel I (3-5) and the lifting system belt wheel II (3-7) are connected through a lifting system belt (3-6), the lifting system belt wheel II (3-7) is connected with a threaded shaft (3-8), the threaded shaft (3-8) is rotationally connected with a threaded shaft bracket (3-9), the threaded shaft bracket (3-9) is connected with a stirring barrel (3-2), the threaded shaft (3-8) is in threaded connection with a lifting scrap iron supporting plate (3-10), the lifting scrap iron supporting plate (3-10) is in sliding connection with two supporting plate sliding rails (3-11), the two supporting plate sliding rails (3-11) are both connected with the stirring barrel (3-2), the motor II (3-12) is connected with a motor II bracket (3-13), the motor II bracket (3-13) is connected with an end cover (3-15), the end cover (3-15) is connected with an inner gear ring (3-16), the inner gear ring (3-16) is connected with a support frame (3-17), the support frame (3-17) is connected with a stirring barrel (3-2), a motor II (3-12) is connected with a motor II shaft (3-14), the motor II shaft (3-14) is rotatably connected with the end cover (3-15), the motor II shaft (3-14) is connected with a sun gear (3-18), the sun gear (3-18) is in meshing link with two planetary gears (3-20), the two planetary gears (3-20) are in meshing link with the inner gear ring (3-16), the two planetary gears (3-20) are connected with two planetary gear shafts (3-21), and the two planetary gear shafts (3-21), The second motor shaft (3-14) is rotatably connected with the planetary system support (3-19), the two planetary gear shafts (3-21) are connected with the two spiral blades (3-22), the second motor shaft (3-14) is connected with the fan blades (3-23), the sliding handle (3-24) is slidably connected with the handle sliding groove (3-25), the handle sliding groove (3-25) is positioned on the stirring barrel (3-2), the sliding handle (3-24) is connected with the outlet baffle (3-26), the lower part of the stirring barrel (3-2) is provided with an outlet, the pressing channel (3-27) is connected with the outlet of the stirring barrel (3-2), the two pressing cutters (3-28) are slidably connected with the pressing channel (3-27), and two ends of the two tension springs (3-29) are respectively connected with the two pressing cutters (3-28), The two sides of the pressing channel (3-27) are connected, the two tension springs (3-29) are in a normal state, and the supporting plate (3-30) is connected with the pressing channel (3-27).

5. The scrap iron recycling and processing equipment as claimed in claim 1, wherein the scrap iron recycling and processing equipment comprises: the conveying assembly (4) comprises a conveying system belt (4-1), conveying system belt wheels (4-2), a central shaft (4-3), conveying discs (4-4), a rotating frame (4-5), threaded cylinders (4-6), a shifting plate (4-7) and conveying rails (4-8), wherein the supporting plate (3-30) is connected with the conveying rails (4-8), the two conveying system belt wheels (4-2) are connected through the conveying system belt (4-1), the two conveying system belt wheels (4-2) are respectively connected with a motor II shaft (3-14) and the central shaft (4-3), the central shaft (4-3) is rotatably connected with the bottom plate (1-4), and the central shaft (4-3) is connected with the conveying discs (4-4), The rotating frames (4-5) are connected, the rotating frames (4-5) are connected with four threaded cylinders (4-6), the four threaded cylinders (4-6) are respectively in threaded connection with four shifting plates (4-7), and the conveying tracks (4-8) are not in contact with the conveying discs (4-4).

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