CN113231162A - Aluminum scrap crushing equipment - Google Patents

Abstract

The invention relates to the technical field of waste recovery, in particular to aluminum scrap crushing equipment, wherein a dredging device is used for dredging when blockage occurs, a first clutch and a second clutch are meshed through a rotating rod, a first driving rack is meshed with a first straight gear, a driving gear shaft and a driven gear shaft are rotated to drive a second driving belt, so that a dredging plate compresses aluminum scraps, a compression device compresses the aluminum scraps into blocks after the aluminum scraps are crushed into slag, the second straight gear is meshed with a second gear shaft and a gear at the end face through the sliding of a trigger rod, a driving lead screw is in threaded connection with a first sliding block, a lifting support II drives a roller to rotate in a sliding rail, a carrying assembly transports the aluminum scrap slag, the third gear shaft drives a rack to convey the aluminum scrap blocks through the sliding of the trigger block, and the third gear shaft drives the rack to convey the aluminum scrap blocks, so that the aluminum scraps can be dredged when the blockage occurs, can be effectively solved.

Description

Aluminum scrap crushing equipment

Technical Field

The invention relates to the technical field of waste recovery, in particular to aluminum scrap crushing equipment.

Background

When aluminum scrap crushers in some factories crush aluminum scrap, the problem that the aluminum scrap is blocked cannot be effectively solved, for example, a novel axially adjustable forged hub aluminum scrap crusher with the patent number of CN202020556375.7, a horizontal right-angle gear motor is fixedly installed on the right side above a main installation plate, an elastic coupling is installed on an output shaft of the horizontal right-angle gear motor, a driving shaft is installed on a shaft hole at the other end of the elastic coupling in a matched manner, and a driving gear is installed on the shaft hole on the driving shaft in a matched manner; a square box is fixedly arranged on the left side of the main mounting plate, and the square box is of a structure in which four steel plates with the thickness of 30mm are aligned and combined and connected with each other; two bearing supports are respectively arranged on the left side and the right side of the square box, the driving shaft is arranged on the two bearing supports, the driven shaft is arranged on the other two bearing supports, and a driven gear is arranged on the shaft hole of the driven shaft in a matching way; the driving gear and the driven gear are installed in a tooth meshing manner, and two end faces are aligned; a group of blade assemblies are respectively and fixedly arranged on the driving shaft and the driven shaft relatively; the hopper is fixedly arranged at the upper part of the square box, the hopper is of a lower closing-up structure, the front side of the hopper is designed to be of an open notch structure, a feeding slide is arranged at the position of the open notch in a lap joint mode, and the feeding slide is fixedly supported on the ground through four supporting legs and is coplanar with the lower surface of the main mounting plate; the feeding slide is installed in a manner of inclining a certain angle with the horizontal plane, and a strong magnetic plate is fixedly installed on the feeding slide; the bearing support is internally provided with a double-row bearing, the excircle of the double-row bearing is matched and installed with a shaft hole of the bearing support, the inner circle of the double-row bearing is matched and installed with the shaft hole relative to the driving shaft or the driven shaft, the bearing support is internally provided with a round nut in a thread matching way, the excircle of the round nut is of a thread structure, the inner side end surface of the round nut is attached to the outer ring end surface of the double-row bearing, the outer side end surface of each round nut is provided with three connecting plates, the end surface of the round nut is designed with a plurality of thread holes, the thread holes share one reference circle, the outer side end surface of the bearing support is also designed with a plurality of thread holes, the thread holes share one reference circle, the connecting plates are designed with three mounting holes, and two holes are locked on the round nut through screws, another hole passes through the mounting of screw locking on bearing, three connecting plate be triangle-shaped fixed mounting, novel adjustable forging wheel hub aluminium bits rubbing crusher of axial compares with prior art scheme, conveniently adjusts the installation clearance to technical scheme's reliability and security have been improved, but meet the condition of jam still can't be solved when burning the aluminium bits.

Disclosure of Invention

The invention aims to provide aluminum scrap crushing equipment which can be dredged by a dredging device under the condition of blockage, wherein the compressing device is used for compressing aluminum scraps into blocks after the aluminum scraps are crushed into slag, and a carrying assembly is used for transporting the aluminum scrap slag.

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

the utility model provides an aluminium bits crushing apparatus, includes pull throughs, compressor arrangement, delivery subassembly, the pull throughs is connected with the compressor arrangement cooperation, and the pull throughs is connected with the delivery subassembly cooperation, and the compressor arrangement is connected with the delivery subassembly cooperation.

As a further optimization of the technical scheme, the invention relates to aluminum scrap crushing equipment, wherein the dredging device comprises an aluminum scrap crushing box, a cross rod sleeve, a sleeve support, a first transmission belt, a cutter shaft, a driving gear, a driven gear, a blade, a rotating rod, a cylindrical pin, a transmission shaft sleeve, a first transmission shaft, a cross rod, a first clutch, a second clutch, a rotating arm, a sliding bearing, a sliding chute, a first rack, a first straight gear, a driving gear shaft, a driven gear shaft, a second transmission belt, a first gear shaft, a second rack and a dredging plate, the cross rod sleeve is rotatably connected with the sleeve support, the sleeve support is fixedly connected with the aluminum scrap crushing box, the first transmission belt is cooperatively connected with the cross rod sleeve, the first transmission belt is cooperatively connected with the cutter shaft, the cutter shaft is rotatably connected with the aluminum scrap crushing box, the cutter shaft is fixedly connected with the driving gear, the cutter shaft is fixedly connected with the driven gear, and the cutter shaft is fixedly connected with the blade, the driving gear is meshed with the driven gear, the rotating rod is fixedly connected with the cylindrical pin, the cylindrical pin is fixedly connected with the aluminum scrap crushing box, the transmission shaft sleeve is slidably connected with the rotating rod, the first transmission shaft is rotatably connected with the transmission shaft sleeve, the first transmission shaft is fixedly connected with the cross rod, the cross rod is slidably connected with the cross rod sleeve, the cross rod is fixedly connected with the first clutch, the first clutch is meshed with the second clutch, the second clutch is fixedly connected with the rotating arm, the rotating arm is rotatably connected with the aluminum scrap crushing box, the rotating arm is slidably connected with the sliding bearing, the sliding bearing is slidably connected with the sliding chute, the sliding chute is slidably connected with the aluminum scrap crushing box, the sliding chute is fixedly connected with the first rack, the first rack is meshed with the first straight gear, the first straight gear is fixedly connected with the driving gear shaft, the driving gear shaft is rotatably connected with the aluminum scrap crushing box, the driving gear shaft is meshed with the driven gear shaft, and the driven gear shaft is rotatably connected with the aluminum scrap crushing box, the second transmission belt is connected with the driving gear shaft in a matched mode, the second transmission belt is connected with the driven gear shaft in a matched mode, the second transmission belt is connected with the first gear shaft in a matched mode, the first gear shaft is connected with the aluminum scrap smashing box in a rotating mode, the first gear shaft is connected with the second rack in a meshed mode, the second rack is fixedly connected with the dredging plate, and the dredging plate is connected with the aluminum scrap smashing box in a sliding mode.

As a further optimization of the technical scheme, the invention relates to aluminum scrap crushing equipment, wherein a compression device comprises a compression box, a half gear shaft, a third rack, a compression plate, a first spring, a bearing plate, a trigger rod, a second spring, a second transmission shaft, a second straight gear, a gear support, a second gear shaft, a second end face gear, a lead screw, a fixed rod, a first lifting support, a second lifting support, a first slide block, a roller and a slide rail, wherein the compression box is fixedly connected with the aluminum scrap crushing box, the half gear shaft is rotatably connected with the compression box, the half gear shaft is meshed with the third rack, the third rack is fixedly connected with the compression plate, the compression plate is slidably connected with the compression box, one end of the spring is contacted with the compression box, the other end of the spring is contacted with the compression plate, the bearing plate is slidably connected with the compression box, the trigger rod is slidably connected with the bearing plate, the trigger rod is fixedly connected with the second transmission shaft, one end of the spring is contacted with the compression box, the other end of the spring II is in contact with the trigger rod, the transmission shaft II is fixedly connected with the straight gear II, the gear support is rotatably connected with the transmission shaft II, the gear support is rotatably connected with the gear shaft II, the end face gear is meshed with the straight gear II, the end face gear is meshed with the gear shaft II, the end face gear is fixedly connected with the lead screw, the lead screw is rotatably connected with the fixed rod, the lead screw is in threaded connection with the sliding block I, the fixed rod is fixedly connected with the sliding rail, the lifting support I is fixedly connected with the bearing plate, the lifting support I is fixedly connected with the fixed rod, the lifting support II is fixedly connected with the bearing plate, the lifting support II is fixedly connected with the sliding block I, the sliding block I is fixedly connected with the roller, and the roller is rotatably connected with the sliding rail.

As a further optimization of the technical scheme, the invention relates to aluminum scrap crushing equipment, which comprises a motor, a transmission belt support, a transmission belt III, a transmission belt IV, a bevel gear shaft I, a bevel gear shaft support I, a bevel gear shaft II, a bevel gear shaft support II, a transmission belt V, a roller, a transmission belt VI, a bevel gear I, a transmission belt VII, a bevel gear shaft III, a bevel gear II, a trigger block, a spring III, a bevel gear III, a gear shaft III, a rack IV, a slide block II, an optical axis, a spring IV and an aluminum scrap block support, wherein the motor is fixedly connected with the transmission belt support, the transmission belt III is connected with the motor in a matching way, the transmission belt III is connected with a cross rod sleeve in a matching way, the transmission belt IV is connected with the bevel gear shaft I in a matching way, the bevel gear shaft I is rotationally connected with the bevel gear shaft support, the bevel gear shaft I is connected with the bevel gear shaft II in a meshing way, the bevel gear shaft I is connected with the bevel gear shaft I in a matching way, a bevel gear shaft II is rotatably connected with a bevel gear shaft bracket II, a transmission belt V is in matched connection with the bevel gear shaft II, the transmission belt V is in matched connection with a roller, the roller is in rotated connection with a transmission belt bracket, the roller is in matched connection with a transmission belt, a transmission belt VI is in matched connection with a roller, the transmission belt VI is in matched connection with a half gear shaft, a bevel gear I is fixedly connected with a bevel gear shaft III, a transmission belt VII is in matched connection with the bevel gear shaft III, the transmission belt VII is in matched connection with a transmission shaft II, the bevel gear shaft III is rotatably connected with the transmission belt bracket, the bevel gear II is in meshed connection with the bevel gear shaft III, the bevel gear II is fixedly connected with a trigger block, the trigger block is slidably connected with the transmission belt bracket, one end of a spring III is contacted with the transmission belt bracket, the other end of the spring III is contacted with the trigger block, the bevel gear III is fixedly connected with a gear shaft III, and the gear shaft III is rotatably connected with the transmission belt bracket, the gear shaft III is meshed with the rack IV, the rack IV is fixedly connected with the sliding block II, the sliding block II is connected with the optical axis in a sliding mode, the optical axis is fixedly connected with the transmission belt support, one end of the spring IV is in contact with the transmission belt support, the other end of the spring IV is in contact with the sliding block II, and the aluminum scrap block support is fixedly connected with the rack IV.

The aluminum scrap crushing equipment has the beneficial effects that:

the invention relates to aluminum scrap crushing equipment, wherein a dredging device rotates through a rotating rod, so that a first clutch is meshed with a second clutch, a first driving rack is meshed with a first straight gear, the driving gear shaft and the driven gear shaft rotate to drive the second transmission belt, so that the dredging plate compresses the aluminum scraps, the compression device compresses the aluminum scraps by the sliding of the trigger rod, so that the second straight gear and the second gear shaft are meshed with the gear on the end face, the driving screw rod is in threaded connection with the first sliding block, so that the second lifting bracket drives the roller to rotate in the slide rail, the carrying component slides through the trigger block, and then the second bevel gear is meshed with the third bevel gear shaft and the third bevel gear shaft, and the third bevel gear shaft drives the fourth rack to convey the aluminum scrap blocks.

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 structural view of the dredging device of the present invention;

FIG. 3 is a schematic structural view II of the dredging device of the present invention;

FIG. 4 is a third structural view of the dredging device of the present invention;

FIG. 5 is a fourth schematic structural view of the pull through of the present invention;

FIG. 6 is a fifth structural schematic view of the dredging device of the present invention;

FIG. 7 is a sixth schematic view of the pull through of the present invention;

FIG. 8 is a first schematic view of the compression apparatus of the present invention;

FIG. 9 is a second schematic view of the compression apparatus of the present invention;

FIG. 10 is a third schematic view of the compression apparatus of the present invention;

FIG. 11 is a fourth schematic structural view of the compression apparatus of the present invention;

FIG. 12 is a fifth schematic view of the compression apparatus of the present invention;

FIG. 13 is a sixth schematic view of the compression apparatus of the present invention;

FIG. 14 is a first schematic view of a carrier assembly of the present invention;

FIG. 15 is a second schematic view of the carrier assembly of the present invention;

fig. 16 is a third schematic structural view of the carrier assembly of the present invention.

In the figure: a dredging device 1; 1-1 of an aluminum scrap crushing box; a cross-bar sleeve 1-2; 1-3 of a sleeve support; 1-4 parts of a first transmission belt; 1-5 of a cutter shaft; driving gears 1-6; 1-7 of a driven gear; 1-8 parts of blades; rotating the rods 1-9; 1-10 parts of a cylindrical pin; a transmission shaft sleeve 1-11; 1-12 parts of a first transmission shaft; 1-13 of a cross bar; a first clutch 1-14; a second clutch 1-15; rotating arms 1-16; plain bearings 1-17; 1-18 of a chute; racks I1-19; 1-20 parts of a straight gear I; drive gear shafts 1-21; driven gear shafts 1 to 22; a second transmission belt 1-23; gear shafts 1-24; a second rack 1-25; dredging plates 1-26; a compression device 2; 2-1 of a compression box; a half gear shaft 2-2; 2-3 of a rack; 2-4 of a compression plate; 2-5 parts of a first spring; 2-6 parts of a bearing plate; 2-7 of a trigger rod; 2-8 parts of a second spring; 2-9 parts of a second transmission shaft; 2-10 parts of a second straight gear; 2-11 parts of a gear bracket; 2-12 parts of a second gear shaft; 2-13 of face gear; 2-14 parts of a lead screw; 2-15 parts of a fixed rod; 2-16 parts of a lifting support I; 2-17 parts of a second lifting support; 2-18 parts of a first sliding block; 2-19 of rollers; 2-20 parts of a slide rail; a carrier assembly 3; a motor 3-1; a transmission belt bracket 3-2; 3-3 parts of a transmission belt III; a fourth transmission belt 3-4; 3-5 parts of a bevel gear shaft I; a bevel gear shaft support I3-6; 3-7 parts of a second bevel gear shaft; a second bevel gear shaft support 3-8; 3-9 parts of a transmission belt; 3-10 parts of rollers; 3-11 of a conveyor belt; six transmission belts 3-12; 3-13 parts of a first bevel gear; a transmission belt seventh 3-14; 3-15 parts of a bevel gear shaft; bevel gears II 3-16; trigger blocks 3-17; 3-18 parts of a spring; bevel gears three 3-19; 3-20 parts of a gear shaft; rack four 3-21; 3-22 parts of a second sliding block; optical axis 3-23; a fourth spring 3-24; 3-25 parts of aluminum scrap block bracket.

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; 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 following describes the present embodiment with reference to fig. 1 to 16, and an aluminum scrap crushing apparatus includes a dredging device 1, a compressing device 2, and a carrying assembly 3, where the dredging device 1 is connected with the compressing device 2 in a matching manner, the dredging device 1 is connected with the carrying assembly 3 in a matching manner, and the compressing device 2 is connected with the carrying assembly 3 in a matching manner.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-16, and the embodiment will be further described, wherein the dredging device 1 comprises an aluminum scrap crushing box 1-1, a cross rod sleeve 1-2, a sleeve support 1-3, a transmission belt I1-4, a cutter shaft 1-5, a driving gear 1-6, a driven gear 1-7, a blade 1-8, a rotating rod 1-9, a cylindrical pin 1-10, a transmission shaft sleeve 1-11, a transmission shaft I1-12, a cross rod 1-13, a clutch I1-14, a clutch II 1-15, a rotating arm 1-16, a sliding bearing 1-17, a sliding chute 1-18, a rack I1-19, a spur gear I1-20, a driving gear shaft 1-21, a driven gear shaft 1-22, a driving gear shaft 1-6, a driven gear 1-7, a rotating shaft 1-8, a rotating rod 1-9, a cylindrical pin 1-10, a transmission shaft sleeve 1-11, a transmission shaft 1-12, a cross rod 1-13, a clutch II, a clutch, A second transmission belt 1-23, a first gear shaft 1-24, a second rack 1-25, a dredging plate 1-26, a cross rod sleeve 1-2 rotatably connected with a sleeve support 1-3, the sleeve support 1-3 fixedly connected with an aluminum scrap crushing box 1-1, a first transmission belt 1-4 cooperatively connected with the cross rod sleeve 1-2, a first transmission belt 1-4 cooperatively connected with a cutter shaft 1-5, a cutter shaft 1-5 rotatably connected with the aluminum scrap crushing box 1-1, a cutter shaft 1-5 fixedly connected with a driving gear 1-6, a cutter shaft 1-5 fixedly connected with a driven gear 1-7, a cutter shaft 1-5 fixedly connected with a blade 1-8, a driving gear 1-6 engaged with a driven gear 1-7, a rotating rod 1-9 fixedly connected with a cylindrical pin 1-10, the cylindrical pin 1-10 is fixedly connected with the aluminum scrap crushing box 1-1, the transmission shaft sleeve 1-11 is slidably connected with the rotating rod 1-9, the transmission shaft I1-12 is rotatably connected with the transmission shaft sleeve 1-11, the transmission shaft I1-12 is fixedly connected with the cross rod 1-13, the cross rod 1-13 is slidably connected with the cross rod sleeve 1-2, the cross rod 1-13 is fixedly connected with the clutch I1-14, the clutch I1-14 is engaged with the clutch II 1-15, the clutch II 1-15 is fixedly connected with the rotating arm 1-16, the rotating arm 1-16 is rotatably connected with the aluminum scrap crushing box 1-1, the rotating arm 1-16 is slidably connected with the sliding bearing 1-17, the sliding bearing 1-17 is slidably connected with the sliding chute 1-18, and the sliding chute 1-18 is slidably connected with the aluminum scrap crushing box 1-1, the chutes 1-18 are fixedly connected with the first racks 1-19, the first racks 1-19 are meshed with the first straight gears 1-20, the first straight gears 1-20 are fixedly connected with the driving gear shafts 1-21, the driving gear shafts 1-21 are rotatably connected with the aluminum scrap crushing box 1-1, the driving gear shafts 1-21 are meshed with the driven gear shafts 1-22, the driven gear shafts 1-22 are rotatably connected with the aluminum scrap crushing box 1-1, the transmission belts two 1-23 are matched and connected with the driving gear shafts 1-21, the transmission belts two 1-23 are matched and connected with the driven gear shafts 1-22, the transmission belts two 1-23 are matched and connected with the first gear shafts 1-24, the first gear shafts 1-24 are rotatably connected with the aluminum scrap crushing box 1-1, the first gear shafts 1-24 are meshed and connected with the second racks 1-25, the second rack 1-25 is fixedly connected with the dredging plate 1-26, and the dredging plate 1-26 is slidably connected with the aluminum scrap crushing box 1-1;

aluminum scraps are crushed in an aluminum scrap crushing box 1-and are rotated in a sleeve support 1-3 through a cross rod sleeve 1-2 when the aluminum scraps are crushed and blocked, a transmission belt 1-4 is matched with the cross rod sleeve 1-2 and a cutter shaft 1-5, the cross rod sleeve 1-2 drives the transmission belt 1-4 to transmit, the transmission belt 1-4 drives the cutter shaft 1-5 to rotate, the cutter shaft 1-5 is connected with a driving gear 1-6, a driven gear 1-7 and a blade 1-8, the driving gear 1-6 is meshed with the driven gear 1-7, the driving blade 1-8 is driven to crush the aluminum scraps, and when the aluminum scraps crushing box 1-1 is blocked, the aluminum scraps are rotated in a cylindrical pin 1-10 through a rotating rod 1-9, rotating the rod 1-9 to drive the transmission shaft sleeve 1-11 to slide in the transmission shaft I1-12, so that the cross rod 1-13 slides in the cross rod sleeve 1-2, the cross rod 1-13 is connected with the clutch I1-14, the clutch I1-14 is driven to be meshed with the clutch II 1-15 after the cross rod 1-13 slides, the clutch II 1-15 is connected with the rotating arm 1-16, the rotating arm 1-16 is driven to rotate after the clutch II 1-15 rotates, the rotating arm 1-16 drives the sliding bearing 1-17 to slide, so that the sliding bearing 1-17 drives the sliding chute 1-18 to slide on the aluminum scrap crushing box 1-1, the sliding chute 1-18 is connected with the rack I1-19, the rack I1-19 is driven to be meshed with the straight gear I1-20 after the sliding chute 1-18 slides, the first straight gear 1-20 is connected with the driving gear shaft 1-21, the driving gear shaft 1-21 is driven to be meshed with the driven gear shaft 1-22 after the first straight gear 1-20 rotates, the driving belt II 1-23 is matched with the driving gear shaft 1-21, the driven gear shaft 1-22 and the gear shaft I1-24, after the driving gear shaft 1-21 is meshed with the driven gear shaft 1-22, driving the second transmission belts 1-23 at the two sides to transmit, driving the first gear shafts 1-24 to rotate by the second transmission belts 1-23, the gear shaft I1-24 is meshed with the rack II 1-25 after rotating, the rack II 1-25 is driven to slide, the rack II 1-25 is connected with the dredging plate 1-26, so that the dredging plates 1-26 at the two sides dredge the aluminum scraps blocked in the aluminum scrap crushing box 1-1.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-16, and the embodiment further describes the first embodiment, wherein the compression device 2 comprises a compression box 2-1, a half gear shaft 2-2, a rack three 2-3, a compression plate 2-4, a spring one 2-5, a bearing plate 2-6, a trigger rod 2-7, a spring two 2-8, a transmission shaft two 2-9, a spur gear two 2-10, a gear support 2-11, a gear shaft two 2-12, an end face gear 2-13, a screw rod 2-14, a fixed rod 2-15, a lifting support one 2-16, a lifting support two 2-17, a slide block one 2-18, a roller 2-19 and a slide rail 2-20, the compression box 2-1 is fixedly connected with the aluminum scrap crushing box 1-1, the half gear shaft 2-2 is rotatably connected with the compression box 2-1, a half gear shaft 2-2 is meshed with a rack III 2-3, the rack III 2-3 is fixedly connected with a compression plate 2-4, the compression plate 2-4 is slidably connected with a compression box 2-1, one end of a spring I2-5 is contacted with the compression box 2-1, the other end of the spring I2-5 is contacted with the compression plate 2-4, a bearing plate 2-6 is slidably connected with the compression box 2-1, a trigger rod 2-7 is slidably connected with the bearing plate 2-6, a trigger rod 2-7 is fixedly connected with a transmission shaft II 2-9, one end of the spring II 2-8 is contacted with the compression box 2-1, the other end of the spring II 2-8 is contacted with the trigger rod 2-7, the transmission shaft II 2-9 is fixedly connected with a straight gear II 2-10, a gear bracket 2-11 is rotatably connected with the transmission shaft II 2-9, the gear support 2-11 is rotatably connected with a gear shaft II 2-12, the end face gear 2-13 is meshed with a straight gear II 2-10, the end face gear 2-13 is meshed with a gear shaft II 2-12, the end face gear 2-13 is fixedly connected with a screw rod 2-14, the screw rod 2-14 is rotatably connected with a fixed rod 2-15, the screw rod 2-14 is in threaded connection with a slide block I2-18, the fixed rod 2-15 is fixedly connected with a slide rail 2-20, the lifting support I2-16 is fixedly connected with a bearing plate 2-6, the lifting support I2-16 is fixedly connected with the fixed rod 2-15, the lifting support II 2-17 is fixedly connected with the bearing plate 2-6, the lifting support II 2-17 is fixedly connected with the slide block I2-18, and the slide block I2-18 is fixedly connected with a roller 2-19, the rollers 2-19 are rotationally connected with the slide rails 2-20;

after aluminum scraps are crushed, in a compression box 2-1, through rotation of a half gear shaft 2-2, meshing of the half gear shaft 2-2 and a rack III 2-3 drives the rack III 2-3 to slide, the rack III 2-3 is connected with a compression plate 2-4, when the half gear shaft 2-2 is meshed with the rack III 2-3, the compression plate 2-4 is driven to stretch a spring I2-5 to compress the aluminum scraps, when the half gear shaft 2-2 is disconnected with the rack III 2-3, the spring I2-5 drives the compression plate 2-4 to retract, a bearing plate 2-6 loads the aluminum scraps, when the aluminum scraps are contacted with a trigger rod 2-7, a spring II 2-8 is carried out through the trigger rod 2-7, the trigger rod 2-7 is connected with a transmission shaft II 2-9, A second straight gear 2-10, a second gear shaft 2-12 of a second gear bracket 2-11 is fixed on a second transmission shaft 2-9, when a trigger rod 2-7 slides, the second straight gear 2-10 is meshed with an end face gear 2-13, the end face gear 2-13 is connected with a lead screw 2-14, the end face gear 2-13 rotates to drive the lead screw 2-14 to be in threaded connection with a first slide block 2-18, so that the first slide block 2-18 drives a roller 2-19 to rotate on a slide rail 2-20 to drive a second lifting bracket 2-17 to slide, so that a bearing plate 2-6 slides downwards, after aluminum scrap is transmitted, a second spring 2-8 is released, the second transmission shaft 2-9 is driven by the trigger rod 2-7 to enable the second gear shaft 2-12 to be meshed with the end face gear 2-13, the face gears 2-13 are reversely rotated, the lead screws 2-14 drive the first sliding blocks 2-18 to slide, the first sliding blocks 2-18 drive the rollers 2-19 to rotate on the sliding rails 2-20, the second lifting supports 2-17 are driven to slide, so that the bearing plates 2-6 are upward, the first lifting supports 2-16 are fixed on the bearing plates 2-6, and the second lifting supports 2-17 slide with the first lifting supports 2-16 as fulcrums.

The fourth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-16, and the carrier assembly 3 includes a motor 3-1, a belt support 3-2, a belt third 3-3, a belt fourth 3-4, a bevel gear shaft first 3-5, a bevel gear shaft support first 3-6, a bevel gear shaft second 3-7, a bevel gear shaft support second 3-8, a belt fifth 3-9, rollers 3-10, a belt 3-11, a belt sixth 3-12, a bevel gear first 3-13, a belt seventh 3-14, a bevel gear shaft third 3-15, a bevel gear second 3-16, a trigger block 3-17, a spring third 3-18, a bevel gear third 3-19, a gear shaft third 3-20, a rack fourth 3-21, a slide block second 3-22, 3-23 parts of an optical shaft, 3-24 parts of a spring, 3-25 parts of an aluminum scrap block bracket, 3-1 parts of a motor and 3-2 parts of a transmission belt bracket, 3-3 parts of a transmission belt III is connected with the motor 3-1 in a matching way, 3-3 parts of the transmission belt III is connected with a cross rod sleeve 1-2 in a matching way, 3-4 parts of the transmission belt IV is connected with the motor 3-1 in a matching way, 3-4 parts of the transmission belt IV is connected with a first bevel gear shaft 3-5 in a matching way, 3-5 parts of the first bevel gear shaft I is rotationally connected with a first bevel gear bracket 3-6, 3-5 parts of the first bevel gear shaft I is meshed with a second bevel gear shaft 3-7, 3-13 parts of the first bevel gear shaft I, 3-7 parts of the second bevel gear shaft is rotationally connected with a second bevel gear shaft bracket 3-8, and 3-9 parts of the transmission belt V is connected with a second bevel gear shaft 3-7 in a matching way, five transmission belts 3-9 are in fit connection with the rollers 3-10, the rollers 3-10 are in rotational connection with a transmission belt bracket 3-2, the rollers 3-10 are in fit connection with the transmission belts 3-11, six transmission belts 3-12 are in fit connection with the rollers 3-10, six transmission belts 3-12 are in fit connection with a half gear shaft 2-2, a first bevel gear 3-13 is fixedly connected with a third bevel gear 3-15, a seventh transmission belt 3-14 is in fit connection with the third bevel gear 3-15, a seventh transmission belt 3-14 is in fit connection with a second transmission shaft 2-9, the third bevel gear 3-15 is in rotational connection with the transmission belt bracket 3-2, a second bevel gear 3-16 is in mesh connection with the third bevel gear 3-15, and a second bevel gear 3-16 is in mesh connection with the third bevel gear 3-19, the second bevel gear 3-16 is fixedly connected with the trigger block 3-17, the trigger block 3-17 is slidably connected with the transmission belt bracket 3-2, one end of the third spring 3-18 is contacted with the transmission belt bracket 3-2, the other end of the third spring 3-18 is contacted with the trigger block 3-17, the third bevel gear 3-19 is fixedly connected with the third gear shaft 3-20, the third gear shaft 3-20 is rotatably connected with the transmission belt bracket 3-2, the third gear shaft 3-20 is meshed with the fourth rack 3-21, the fourth rack 3-21 is fixedly connected with the second slider 3-22, the second slider 3-22 is slidably connected with the optical axis 3-23, the optical axis 3-23 is fixedly connected with the transmission belt bracket 3-2, one end of the fourth spring 3-24 is contacted with the transmission belt bracket 3-2, the other end of the fourth spring 3-24 is contacted with the second slider 3-22, the aluminum scrap block bracket 3-25 is fixedly connected with the rack four 3-21.

The invention relates to aluminum scrap crushing equipment, which has the working principle that: aluminum scraps are crushed in an aluminum scrap crushing box 1-and are rotated in a sleeve support 1-3 through a cross rod sleeve 1-2 when the aluminum scraps are crushed and blocked, a transmission belt 1-4 is matched with the cross rod sleeve 1-2 and a cutter shaft 1-5, the cross rod sleeve 1-2 drives the transmission belt 1-4 to transmit, the transmission belt 1-4 drives the cutter shaft 1-5 to rotate, the cutter shaft 1-5 is connected with a driving gear 1-6, a driven gear 1-7 and a blade 1-8, the driving gear 1-6 is meshed with the driven gear 1-7, the driving blade 1-8 is driven to crush the aluminum scraps, and when the aluminum scraps crushing box 1-1 is blocked, the aluminum scraps are rotated in a cylindrical pin 1-10 through a rotating rod 1-9, rotating the rod 1-9 to drive the transmission shaft sleeve 1-11 to slide in the transmission shaft I1-12, so that the cross rod 1-13 slides in the cross rod sleeve 1-2, the cross rod 1-13 is connected with the clutch I1-14, the clutch I1-14 is driven to be meshed with the clutch II 1-15 after the cross rod 1-13 slides, the clutch II 1-15 is connected with the rotating arm 1-16, the rotating arm 1-16 is driven to rotate after the clutch II 1-15 rotates, the rotating arm 1-16 drives the sliding bearing 1-17 to slide, so that the sliding bearing 1-17 drives the sliding chute 1-18 to slide on the aluminum scrap crushing box 1-1, the sliding chute 1-18 is connected with the rack I1-19, the rack I1-19 is driven to be meshed with the straight gear I1-20 after the sliding chute 1-18 slides, the first straight gear 1-20 is connected with the driving gear shaft 1-21, the driving gear shaft 1-21 is driven to be meshed with the driven gear shaft 1-22 after the first straight gear 1-20 rotates, the transmission belt II 1-23 is matched with the driving gear shaft 1-21, the driven gear shaft 1-22 and the gear shaft I1-24, the driving gear shaft 1-21 is meshed with the driven gear shaft 1-22, the transmission belts II 1-23 on the two sides are driven to transmit, the transmission belts II 1-23 drive the gear shafts I1-24 to rotate, the gear shafts I1-24 are meshed with the rack II 1-25 after rotating, the driving rack II 1-25 slides, the rack II 1-25 is connected with the dredging plates 1-26, so that the dredging plates 1-26 on the two sides dredge aluminum scraps blocked in the aluminum scrap crushing box 1-1, after aluminum scraps are crushed, in a compression box 2-1, through rotation of a half gear shaft 2-2, meshing of the half gear shaft 2-2 and a rack III 2-3 drives the rack III 2-3 to slide, the rack III 2-3 is connected with a compression plate 2-4, when the half gear shaft 2-2 is meshed with the rack III 2-3, the compression plate 2-4 is driven to stretch a spring I2-5 to compress the aluminum scraps, when the half gear shaft 2-2 is disconnected with the rack III 2-3, the spring I2-5 drives the compression plate 2-4 to retract, a bearing plate 2-6 loads the aluminum scraps, when the aluminum scraps are contacted with a trigger rod 2-7, a spring II 2-8 is carried out through the trigger rod 2-7, the trigger rod 2-7 is connected with a transmission shaft II 2-9, A second straight gear 2-10, a second gear shaft 2-12 of a second gear bracket 2-11 is fixed on a second transmission shaft 2-9, when a trigger rod 2-7 slides, the second straight gear 2-10 is meshed with an end face gear 2-13, the end face gear 2-13 is connected with a lead screw 2-14, the end face gear 2-13 rotates to drive the lead screw 2-14 to be in threaded connection with a first slide block 2-18, so that the first slide block 2-18 drives a roller 2-19 to rotate on a slide rail 2-20 to drive a second lifting bracket 2-17 to slide, so that a bearing plate 2-6 slides downwards, after aluminum scrap is transmitted, a second spring 2-8 is released, the second transmission shaft 2-9 is driven by the trigger rod 2-7 to enable the second gear shaft 2-12 to be meshed with the end face gear 2-13, the end face gear 2-13 is reversely rotated, the screw rod 2-14 drives the first slide block 2-18 to slide, the first slide block 2-18 drives the roller 2-19 to rotate on the slide rail 2-20 to drive the second lifting support 2-17 to slide, so that the bearing plate 2-6 is upward, the first lifting support 2-16 is fixed on the bearing plate 2-6, the second lifting support 2-17 slides by taking the first lifting support 2-16 as a fulcrum, the motor 3-1 outputs the whole equipment, the motor 3-1 is fixed on the transmission belt support 3-2, the third transmission belt 3-3 is matched with the motor 3-1 and the cross rod sleeve 1-2, and the third transmission belt 3-3 drives the cross rod sleeve 1-2 to rotate after transmission, the dredging device is enabled to run, a driving belt IV 3-4 is matched with a motor 3-1 and a bevel gear shaft I3-5, the driving belt IV 3-4 drives the bevel gear shaft I3-5 to rotate in a bevel gear shaft bracket I3-6, the bevel gear shaft I3-5 is meshed with a bevel gear shaft II 3-7 and a bevel gear I3-13, the driving belt IV 3-5 drives the bevel gear shaft II 3-7 to rotate in a bevel gear shaft bracket II 3-8, a driving belt V3-9 is matched with the bevel gear shaft II 3-7 and a roller 3-10, the driving belt V3-7 drives the driving belt V3-9 to transmit, the driving belt V3-9 drives the roller 3-10 to rotate in a driving belt bracket 3-2, and the roller 3-10 is matched with a driving belt 3-11, conveying the aluminum scrap slag, matching 3-12 of a transmission belt with 3-10 of rollers and 2-2 of a half gear shaft, driving 3-10 of the transmission belt to six 3-12 of the transmission belt for transmission, driving six 3-12 of the transmission belt to drive 2-2 of the half gear shaft to rotate, enabling a compression device to compress the aluminum scrap slag into blocks, meshing 3-5 of a first bevel gear shaft with 3-13 of a first bevel gear, connecting 3-13 of the first bevel gear shaft with three 3-15 of the third bevel gear shaft, matching 3-14 of the transmission belt with three 3-15 of the bevel gear shaft and 2-9 of a transmission shaft, driving 3-15 of the third bevel gear shaft to drive seven 3-14 of the transmission belt, driving seven 3-14 of the transmission belt to drive two 2-9 of the transmission shaft, enabling two 2-10 of the straight gear to rotate, and enabling a lifting support to operate, the bearing plate 2-6 slides to contact with the trigger block 3-17, so that the trigger block 3-17 slides on the transmission belt bracket 3-2, the trigger block 3-17 is connected with the bevel gear II 3-16, the trigger block 3-17 slides to be connected with the extension spring III 3-18, so that the bevel gear II 3-16 is meshed with the bevel gear shaft III 3-15 and the bevel gear III 3-19, the bevel gear II 3-16 is meshed with the bevel gear shaft III 3-15 and then rotates, so that the bevel gear II 3-16 drives the bevel gear III 3-19 to rotate, the bevel gear III 3-19 is connected with the gear shaft III 3-20, the bevel gear III 3-19 rotates to drive the gear shaft III 3-20 to be meshed with the rack IV 3-21, the rack IV 3-21 is meshed and then slides, the rack IV 3-21 is connected with the sliding block II 3-22 and the aluminum scrap block support 3-25, the sliding block II 3-22 is driven to slide in the optical axis 3-23 by compressing the spring IV 3-24 after the rack IV 3-21 slides, the aluminum scrap block support 3-25 controls the aluminum scrap to be transported, and after the aluminum scrap slag is transported, the lifting support slides upwards to release the spring III 3-18 and drive the bevel gear II 3-16 to be disengaged from the bevel gear shaft III 3-15 and the bevel gear III 3-19, so that the spring IV 3-24 is released and the sliding block II 3-22 is driven to reset.

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 (4)

1. The utility model provides an aluminium bits crushing apparatus which characterized in that: including pull throughs (1), compressor arrangement (2), delivery subassembly (3), pull throughs (1) is connected with compressor arrangement (2) cooperation, and pull throughs (1) is connected with delivery subassembly (3) cooperation, and compressor arrangement (2) is connected with delivery subassembly (3) cooperation.

2. An aluminum scrap crushing apparatus according to claim 1, wherein: the dredging device (1) comprises an aluminum scrap crushing box (1-1), a cross rod sleeve (1-2), a sleeve support (1-3), a transmission belt I (1-4), a cutter shaft I (1-5), a driving gear (1-6), a driven gear (1-7), a blade (1-8), a rotating rod (1-9), a cylindrical pin (1-10), a transmission shaft sleeve (1-11), a transmission shaft I (1-12), a cross rod I (1-13), a clutch I (1-14), a clutch II (1-15), a rotating arm (1-16), a sliding bearing (1-17), a sliding groove (1-18), a rack I (1-19), a straight gear I (1-20), a driving gear shaft I (1-21), a driven gear shaft I (1-22), A second transmission belt (1-23), a first gear shaft (1-24), a second rack (1-25) and a dredging plate (1-26), a cross rod sleeve (1-2) is rotatably connected with a sleeve support (1-3), the sleeve support (1-3) is fixedly connected with an aluminum scrap crushing box (1-1), a first transmission belt (1-4) is connected with the cross rod sleeve (1-2) in a matching way, a first transmission belt (1-4) is connected with a first cutter shaft (1-5) in a matching way, the cutter shaft (1-5) is rotatably connected with the aluminum scrap crushing box (1-1), the cutter shaft (1-5) is fixedly connected with a driving gear (1-6), the cutter shaft (1-5) is fixedly connected with a driven gear (1-7), and the cutter shaft (1-5) is fixedly connected with a blade (1-8), a driving gear (1-6) is meshed with a driven gear (1-7), a rotating rod (1-9) is fixedly connected with a cylindrical pin (1-10), the cylindrical pin (1-10) is fixedly connected with an aluminum scrap crushing box (1-1), a transmission shaft sleeve (1-11) is slidably connected with the rotating rod (1-9), a transmission shaft I (1-12) is rotatably connected with the transmission shaft sleeve (1-11), a transmission shaft I (1-12) is fixedly connected with a cross rod (1-13), the cross rod (1-13) is slidably connected with a cross rod sleeve (1-2), the cross rod (1-13) is fixedly connected with a clutch I (1-14), the clutch I (1-14) is meshed with a clutch II (1-15), the clutch II (1-15) is fixedly connected with a rotating arm (1-16), the rotary arm (1-16) is rotatably connected with the aluminum scrap crushing box (1-1), the rotary arm (1-16) is slidably connected with the sliding bearing (1-17), the sliding bearing (1-17) is slidably connected with the sliding chute (1-18), the sliding chute (1-18) is slidably connected with the aluminum scrap crushing box (1-1), the sliding chute (1-18) is fixedly connected with the rack I (1-19), the rack I (1-19) is meshed with the straight gear I (1-20), the straight gear I (1-20) is fixedly connected with the driving gear shaft (1-21), the driving gear shaft (1-21) is rotatably connected with the aluminum scrap crushing box (1-1), the driving gear shaft (1-21) is meshed with the driven gear shaft (1-22), the driven gear shaft (1-22) is rotatably connected with the aluminum scrap crushing box (1-1), the driving gear shaft (1-21) is connected with the driving belt II (1-23) in a matching mode, the driving belt II (1-23) is connected with the driven gear shaft (1-22) in a matching mode, the driving belt II (1-23) is connected with the gear shaft I (1-24) in a matching mode, the gear shaft I (1-24) is rotatably connected with the aluminum scrap crushing box (1-1), the gear shaft I (1-24) is connected with the rack II (1-25) in a meshing mode, the rack II (1-25) is fixedly connected with the dredging plate (1-26), and the dredging plate (1-26) is connected with the aluminum scrap crushing box (1-1) in a sliding mode.

3. An aluminum scrap crushing apparatus according to claim 1, wherein: the compression device (2) comprises a compression box (2-1), a half gear shaft (2-2), a rack III (2-3), a compression plate (2-4), a spring I (2-5), a bearing plate (2-6), a trigger rod (2-7), a spring II (2-8), a transmission shaft II (2-9), a straight gear II (2-10), a gear support (2-11), a gear shaft II (2-12), an end face gear (2-13), a screw rod (2-14), a fixed rod (2-15), a lifting support I (2-16), a lifting support II (2-17), a slide block I (2-18), a roller (2-19) and a slide rail (2-20), wherein the compression box (2-1) is fixedly connected with the aluminum scrap crushing box (1-1), the half gear shaft (2-2) is rotatably connected with the compression box (2-1), the half gear shaft (2-2) is meshed with the rack III (2-3), the rack III (2-3) is fixedly connected with the compression plate (2-4), the compression plate (2-4) is slidably connected with the compression box (2-1), one end of the spring I (2-5) is contacted with the compression box (2-1), the other end of the spring I (2-5) is contacted with the compression plate (2-4), the bearing plate (2-6) is slidably connected with the compression box (2-1), the trigger rod (2-7) is slidably connected with the bearing plate (2-6), the trigger rod (2-7) is fixedly connected with the transmission shaft II (2-9), one end of the spring II (2-8) is contacted with the compression box (2-1), the other end of the spring II (2-8) is contacted with the trigger rod (2-7), the transmission shaft II (2-9) is fixedly connected with the straight gear II (2-10), the gear bracket (2-11) is rotationally connected with the transmission shaft II (2-9), the gear bracket (2-11) is rotationally connected with the gear shaft II (2-12), the end face gear (2-13) is meshed with the straight gear II (2-10), the end face gear (2-13) is meshed with the gear shaft II (2-12), the end face gear (2-13) is fixedly connected with the screw rod (2-14), the screw rod (2-14) is rotationally connected with the fixed rod (2-15), the screw rod (2-14) is in threaded connection with the sliding block I (2-18), the fixed rod (2-15) is fixedly connected with the sliding rail (2-20), the lifting support I (2-16) is fixedly connected with the bearing plate (2-6), the lifting support I (2-16) is fixedly connected with the fixing rod (2-15), the lifting support II (2-17) is fixedly connected with the bearing plate (2-6), the lifting support II (2-17) is fixedly connected with the sliding block I (2-18), the sliding block I (2-18) is fixedly connected with the roller (2-19), and the roller (2-19) is rotatably connected with the sliding rail (2-20).

4. An aluminum scrap crushing apparatus according to claim 1, wherein: the carrying component (3) comprises a motor (3-1), a transmission belt support (3-2), a transmission belt III (3-3), a transmission belt IV (3-4), a bevel gear shaft I (3-5), a bevel gear shaft support I (3-6), a bevel gear shaft II (3-7), a bevel gear shaft support II (3-8), a transmission belt V (3-9), a roller (3-10), a transmission belt (3-11), a transmission belt VI (3-12), a bevel gear I (3-13), a transmission belt VII (3-14), a bevel gear shaft III (3-15), a bevel gear II (3-16), a trigger block (3-17), a spring III (3-18), a bevel gear III (3-19), a gear shaft III (3-20), a rack IV (3-21), A second sliding block (3-22), an optical axis (3-23), a fourth spring (3-24) and an aluminum scrap block support (3-25), wherein a motor (3-1) is fixedly connected with a transmission belt support (3-2), a third transmission belt (3-3) is connected with the motor (3-1) in a matching way, the third transmission belt (3-3) is connected with a cross rod sleeve (1-2) in a matching way, a fourth transmission belt (3-4) is connected with the motor (3-1) in a matching way, a fourth transmission belt (3-4) is connected with a first bevel gear shaft (3-5) in a matching way, the first bevel gear shaft (3-5) is rotationally connected with a first bevel gear shaft support (3-6), the first bevel gear shaft (3-5) is connected with a second bevel gear shaft (3-7) in a meshing way, the first bevel gear shaft (3-5) is connected with a first bevel gear (3-13) in a matching way, a bevel gear shaft II (3-7) is rotationally connected with a bevel gear shaft bracket II (3-8), a transmission belt fifth (3-9) is in matched connection with the bevel gear shaft II (3-7), a transmission belt fifth (3-9) is in matched connection with a roller (3-10), the roller (3-10) is rotationally connected with a transmission belt bracket (3-2), the roller (3-10) is in matched connection with a transmission belt (3-11), a transmission belt sixth (3-12) is in matched connection with the roller (3-10), the transmission belt sixth (3-12) is in matched connection with a half gear shaft (2-2), a bevel gear I (3-13) is fixedly connected with a bevel gear shaft III (3-15), a transmission belt seventh (3-14) is in matched connection with the bevel gear shaft III (3-15), and a transmission belt seventh (3-14) is in matched connection with a transmission shaft II (2-9), a third bevel gear shaft (3-15) is rotatably connected with a transmission belt bracket (3-2), a second bevel gear (3-16) is meshed with the third bevel gear shaft (3-15), the second bevel gear (3-16) is meshed with a third bevel gear (3-19), the second bevel gear (3-16) is fixedly connected with a trigger block (3-17), the trigger block (3-17) is slidably connected with the transmission belt bracket (3-2), one end of a third spring (3-18) is contacted with the transmission belt bracket (3-2), the other end of the third spring (3-18) is contacted with the trigger block (3-17), the third bevel gear (3-19) is fixedly connected with a third gear shaft (3-20), the third gear shaft (3-20) is rotatably connected with the transmission belt bracket (3-2), the third gear shaft (3-20) is meshed with a fourth rack (3-21), the rack IV (3-21) is fixedly connected with the slide block II (3-22), the slide block II (3-22) is slidably connected with the optical axis (3-23), the optical axis (3-23) is fixedly connected with the transmission belt support (3-2), one end of the spring IV (3-24) is contacted with the transmission belt support (3-2), the other end of the spring IV (3-24) is contacted with the slide block II (3-22), and the aluminum scrap block support (3-25) is fixedly connected with the rack IV (3-21).

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