CN111921606A

CN111921606A - Ore crusher with screening and crushing loading functions

Info

Publication number: CN111921606A
Application number: CN202010705978.3A
Authority: CN
Inventors: 蓝锦
Original assignee: Guangzhou Liji Mining Equipment Co ltd
Current assignee: Guangzhou Liji Mining Equipment Co ltd
Priority date: 2020-07-21
Filing date: 2020-07-21
Publication date: 2020-11-13

Abstract

The invention discloses an ore crusher with screening, crushing and loading functions, which comprises a machine body, a working cavity with an upward opening is arranged in the machine body, a vibration box with an upward opening and capable of slightly moving up and down is arranged in the working cavity, the upper trisection and the lower trisection of the front wall and the rear wall of the vibration box are fixedly provided with two stone filter plates and gravel filter plates with different specifications, the stone filtering plate and the crushed stone filtering plate divide the working cavity into three equal parts, the invention separately conveys mined ores after screening, different procedures are carried out according to different sizes of ores and simultaneously, the large ores and the small ores are finally separated and crushed into small crushed stones, the ores of the crusher are greatly improved, and finally, the crushed stone is output in a reciprocating manner from left to right, so that the crushed stone is conveniently carried to a transport vehicle, and the loading space of the transport vehicle is reasonably utilized to greatly improve the ore mining efficiency.

Description

Ore crusher with screening and crushing loading functions

Technical Field

The invention relates to the technical field of mineral resource exploitation and processing, in particular to an ore crusher with screening, crushing and loading functions.

Background

In our daily life, the mining of ore resources is to mine the earth's surface ore and collect, all need excavate the ore to the transport vechicle through excavating the machine in ordinary ore mining process, some large-scale ore all need to grind the ore back rethread transport vechicle transportation, the ore has big or little shape all inconsistent, some ordinary ore grinding machine all directly carries out the ore grinding, some big ore often can reduce the efficiency of grinding in this process, and some broken granule ore need not repeatedly grind again and has reduced the efficiency of grinding, and ordinary grinding machine all need again load the ore after grinding again and has greatly reduced the efficiency of exploitation. The present invention sets forth a device that solves the above problems.

Disclosure of Invention

The technical problem is as follows: ore mining needs to crush the ore and then carry out loading transportation, and large-scale ore needs to crush and then carries out loading, and ordinary grinding rolls crush inefficiency, and the loading is troublesome.

In order to solve the problems, the ore crusher with the functions of screening, crushing and loading is designed in the embodiment, the ore crusher with the functions of screening, crushing and loading comprises a machine body, a working chamber with an upward opening is arranged in the machine body, a vibration box with an upward opening and capable of slightly moving up and down is arranged in the working chamber, two stone filter plates and a crushed stone filter plate with different specifications are fixedly arranged at the upper trisection position and the lower trisection position of the front wall and the rear wall of the vibration box, the working chamber is trisected by the stone filter plates and the crushed stone filter plates, propulsion chambers with the same size are arranged in the left wall of the working chamber at the upper middle part and the lower part, three propulsion mechanisms with the same structure are arranged in the propulsion chambers, a chain wheel chamber is arranged in the left wall of the propulsion chambers, a transmission mechanism is arranged in the chain wheel chamber and provides power for the propulsion mechanisms, and a vibration chamber is communicated with the lower, the vibration cavity is internally provided with a vibration mechanism, the right side of the working cavity at the upper side is communicated with a stone channel which is obliquely arranged at the right lower side, the right lower side of the stone channel is communicated with a crushing cavity, the front wall and the rear wall of the crushing cavity are communicated and symmetrically provided with reciprocating cavities, the front side and the rear side of the reciprocating cavity are internally provided with reciprocating mechanisms which are the same in mechanism and are symmetrical relative to the crushing cavity, stone filter plates which are the same in specification with the stone filter plates are fixedly arranged between the front wall and the rear wall of the crushing cavity at the lower side, the lower side of each stone filter plate is provided with a stone channel which is communicated with the crushing cavity, the lower side of each stone channel is communicated with a crushing wheel, the left side of the upper wall of the crushing wheel is communicated with the right wall of the working cavity at the middle side, the crushing cavity is internally provided with a crushing mechanism, the lower side of the crushing cavity is fixedly, go out the intercommunication of stone passageway downside and be equipped with the amasss stone chamber, amasss stone chamber upper wall and downside the right wall intercommunication of working chamber, amasss stone intracavity downside intercommunication is equipped with the conveying chamber, the conveying intracavity is equipped with conveying mechanism, amasss stone chamber right wall intercommunication is equipped with out the stone passageway, be equipped with the ore removal chamber that the opening is decurrent in the conveying chamber lower wall, the ore removal intracavity is equipped with the movable block that can remove about, be equipped with discharge mechanism in the movable block and conveniently load the ore output after will smashing.

Preferably, three equal output baffles which can be turned left and right are arranged at the communication position of the upper side working cavity and the stone channel, the communication position of the middle side working cavity and the fragment channel and the communication position of the lower side working cavity and the crushed stone channel, a cylindrical rotating connecting rod is fixedly connected to the upper end face of each output baffle, the rotating connecting rod is rotatably connected to the supporting block, and the upper end face of the supporting block is fixedly connected to the upper, middle and lower sides of the right end face of the vibration box.

Preferably, the pushing mechanism on the upper, middle and lower sides comprises a moving rod which is arranged in the pushing cavity and can move left and right, a threaded rod is connected with the inner circular surface of the moving rod in a threaded manner, and a push plate arranged on the left wall in the working cavity is fixedly connected with the right end surface of the moving rod.

Preferably, the transmission mechanism comprises three driven sprockets with the same size and rotatably arranged in the sprocket cavity, the left end face of the threaded rod extends into the sprocket cavity and is fixedly connected to the three sides of the sprocket cavity respectively, a driving sprocket is rotatably arranged on the lower wall of the sprocket cavity, the same chain is wound between the driving sprocket and the driven sprockets, a driving motor is fixedly arranged on the lower side of the right wall of the sprocket cavity, and the driving sprocket is in power connection with the driving motor.

Preferably, the vibration mechanism comprises a rotation shaft which is arranged in the vibration cavity in a manner of being identical in mechanism and transversely arranged between the left wall and the right wall in a rotating manner, an eccentric rotary drum is fixedly arranged on the outer end face of the rotation shaft, the upper end face of the eccentric rotary drum is abutted to the lower end face of the vibration box, the left end face of the rotation shaft extends to a driving wheel which is fixedly connected in the transmission cavity, a transmission chain is arranged between the driving wheels, and the driving wheel is in power connection with the driving motor at the left end.

Preferably, the reciprocating mechanism comprises rotary discs rotatably arranged on the rear wall in the reciprocating cavity at the left side and the right side, the rotary discs at the left side and the right side are hinged with a rotary connecting rod, a striking plate capable of moving left and right is arranged at one side of the reciprocating cavity close to the crushing cavity, one end of the rotating connecting rod at the left and right sides close to the crushing cavity is hinged with the end surface of the striking plate far away from the crushing cavity, the axle center of the back end surface of the turntable is fixedly connected with a transmission rotating shaft, a gear cavity is arranged in the back wall of the reciprocating cavity, the transmission rotating shaft extends to the rear of the gear cavity and is fixedly provided with a transmission bevel gear, the end face of the crushing cavity, which is close to the gear cavity, in the gear cavity is rotatably provided with a driven bevel gear meshed with the transmission bevel gear, the gear cavity is close to one side wall of the crushing cavity, the inner parts of the left side and the right side are fixedly provided with a reciprocating motor, and the driven bevel gears are respectively in power connection with the left end and the right end of the reciprocating motor.

Preferably, the grinding mechanism comprises a grinding rotating shaft which is arranged between the left wall and the right wall of the grinding cavity in a rotating mode and is symmetrical front to back, a grinding wheel is fixedly connected to the outer circle end face of the grinding rotating shaft, a meshing cavity is arranged in the right wall of the grinding cavity, the right end of the grinding rotating shaft extends to the inside of the meshing cavity and is fixedly connected with a meshing wheel capable of being meshed with a gear, an energy supply motor is fixedly arranged in the right wall of the front side of the meshing cavity, and the meshing wheel is connected to the front side of the meshing cavity in a power supply mode.

Preferably, energy supply motor right side is equipped with the band pulley chamber, the band pulley intracavity antetheca rotates and is equipped with driving pulley, driving pulley power connect in the energy supply motor, band pulley chamber rear side intercommunication is equipped with the belt chamber of vertical direction, band pulley chamber back wall just is located the rotation of belt chamber upside is equipped with power pulley, power pulley axle center fixedly connected with supports the pivot, power pulley excircle terminal surface right side with around being equipped with the belt between the driving pulley, the rotation of belt intracavity lower wall is equipped with from the driving wheel, from the driving wheel with power pulley excircle terminal surface left side is around being equipped with conveyer.

Preferably, conveying mechanism includes that symmetry just rotates around and locates the conveying axle of conveying intracavity left and right sides wall, front side conveying axle right-hand member face extends to belt intracavity and fixed connection in from driving wheel left end face axle center, both sides around being equipped with the conveyer belt between the conveying cylinder, amassman chamber back wall intercommunication is equipped with out the stone passageway, the ore after the conveyer belt will pulverize conveys backward in the stone passageway goes out.

Preferably, the discharging mechanism comprises a discharging connecting pipe which is communicated with the inside of the movable block, the upper side of the discharging connecting pipe is communicated with a stone conveying channel with a telescopic length, the rear side of the stone conveying channel is communicated with the stone outlet channel, the lower side of the discharge connecting pipe is communicated with a material conveying funnel with a downward opening for discharging, the center of the moving block is in threaded connection with a threaded connecting rod, a conveying motor is fixedly arranged in the right wall of the ore removal cavity, the right end of the threaded connecting rod is in power connection with the conveying motor, the end surfaces of the left wall and the right wall of the ore removal cavity are communicated and are symmetrically provided with moving cavities, a pressing block capable of moving left and right is arranged in the moving cavity, an electromagnetic block is fixedly arranged at one end of the pressing block far away from the ore removal cavity, an electromagnetic switch is fixedly arranged on the end face, away from the ore removal cavity, of the moving cavity, and a spring is fixedly connected between the electromagnetic switch and the pressing block.

The invention has the beneficial effects that: according to the invention, ores mined are separated and conveyed after being screened, different processes are carried out according to the ores with different sizes and are carried out simultaneously, the ores with different sizes are finally separated and crushed into small crushed stones, the ores of the crusher are greatly improved, and the crushed stones are finally output in a reciprocating manner from left to right, so that the crushed stones are conveniently carried to a transport vehicle, and the loading space of the transport vehicle is reasonably utilized, thereby greatly improving the ore mining efficiency.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic view of the overall construction of a mineral breaker of the present invention having screening and breaking loading functions;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 1;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 3;

FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 3;

FIG. 7 is a schematic view of the structure in the direction "F-F" of FIG. 1;

fig. 8 is an enlarged view of the structure of "G" in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-8, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to an ore crusher with screening, crushing and loading functions, which comprises a machine body 11, wherein a working chamber 15 with an upward opening is arranged in the machine body 11, a vibration box 30 with an upward opening and capable of slightly moving up and down is arranged in the working chamber 15, two trisections of the upper part and the lower part of the front wall and the rear wall of the vibration box 30 are fixedly provided with a stone filter plate 60 and a gravel filter plate 61 with different specifications, the stone filter plate 60 and the gravel filter plate 61 trisect the working chamber 15, the left wall of the working chamber 15 is provided with a propelling chamber 20 with the same size in the upper, middle and lower three parts, the propelling chamber 20 is internally provided with three propelling mechanisms 101 with the same mechanism, the left wall of the propelling chamber 20 is internally provided with a chain wheel chamber 21, the chain wheel chamber 21 is internally provided with a transmission mechanism 102, the transmission mechanism 102 provides power for the propelling mechanism 101, the lower side of the working chamber 15, the vibrating cavity 68 is internally provided with a vibrating mechanism 103, the right side of the working cavity 15 at the upper side is communicated with and provided with a stone channel 19 inclined to the right lower side, the right lower side of the stone channel 19 is communicated with and provided with a crushing cavity 59, the front wall and the rear wall of the crushing cavity 59 are communicated and symmetrically provided with reciprocating cavities 72, the reciprocating cavities 72 at the front side and the rear side are internally provided with reciprocating mechanisms 104 which have the same mechanism and are symmetrical relative to the crushing cavity 59, stone filter plates 58 with the same specification as the stone filter plates 60 are fixedly arranged between the front wall and the rear wall at the front side and the rear wall at the lower side of the crushing cavity 59, the lower side of each stone filter plate 58 is provided with a stone channel 57 communicated with the crushing cavity 59, the lower side of each stone channel 57 is communicated with and provided with a crushing wheel 55, the left side of the upper wall of the crushing wheel 55 is communicated with the right wall of the working cavity 15 at the middle side, the, the utility model discloses a crushing chamber, including rubble filter 49, crushing chamber 56, conveying chamber 46, conveying mechanism 106, stone discharging channel 48, stone discharging channel 47, working chamber 15, conveying chamber 70, discharge mechanism 107, grinding chamber 48, stone discharging channel 47, working chamber 15, working chamber 38, conveying chamber 46, discharge chamber 70, discharge mechanism 107, conveying chamber 39, ore discharging channel 47, conveying chamber 38, ore discharging chamber 70, conveying chamber 47, conveying chamber.

Advantageously, three equal and left-right-turnable output baffles 12 are arranged at the positions where the upper working chamber 15 is communicated with the stone block channel 19 and the middle working chamber 15 is communicated with the fragment channel 29 and at the positions where the lower working chamber 15 is communicated with the crushed stone channel 28, a cylindrical rotating connecting rod 13 is fixedly connected to the upper end face of each output baffle 12, the rotating connecting rods 13 are rotatably connected to the supporting blocks 14, and the upper end face of each supporting block 14 is fixedly connected to the upper, middle and lower sides of the right end face of the vibration box 30.

Advantageously, the pushing mechanism 101 comprises a moving rod 18 which is arranged in the pushing cavity 20 and can move left and right, a threaded rod 17 is connected to the inner circular surface of the moving rod 18 in a threaded manner, and a pushing plate 16 arranged on the left wall in the working cavity 15 is fixedly connected to the right end surface of the moving rod 18.

Beneficially, the transmission mechanism 102 includes three driven sprockets 22 with the same size and rotatably disposed in the sprocket cavity 21, the left end surfaces of the threaded rods 17 on the upper, middle and lower three sides extend into the sprocket cavity 21 and are fixedly connected to the axes of the right end surfaces of the driven sprockets 22 on the three sides respectively, a driving sprocket 26 is rotatably disposed on the lower wall in the sprocket cavity 21, the same chain 23 is wound between the driving sprocket 26 and the driven sprockets 22 on the upper, middle and lower three sides, a driving motor 27 is fixedly disposed on the inner lower side of the right wall of the sprocket cavity 21, and the driving sprocket 26 is dynamically connected to the driving motor 27.

Beneficially, the vibration mechanism 103 includes a rotation shaft 32 which is arranged in the vibration cavity 68 in a same and transverse array and is rotatably disposed between the left wall and the right wall, an eccentric drum 31 is fixedly disposed on an outer end surface of the rotation shaft 32, an upper end surface of the eccentric drum 31 abuts against a lower end surface of the vibration box 30, a left end surface of the rotation shaft 32 extends into the transmission cavity 37 and is fixedly connected with a driving wheel 33, a transmission chain 88 is wound between each driving wheel 33, and a left end of the driving wheel 33 on a middle side is in power connection with the driving motor 27.

Advantageously, the reciprocating mechanism 104 includes a rotating disc 73 rotatably disposed on the rear wall of the reciprocating cavity 72 on the left and right sides, the rotating disc 73 on the left and right sides is hinged to a rotating link 74, a striking plate 71 capable of moving left and right is disposed on one side of the reciprocating cavity 72 close to the crushing cavity 59, one end of the rotating link 74 on the left and right sides close to the crushing cavity 59 is hinged to the end face of the striking plate 71 away from the crushing cavity 59, a transmission rotating shaft 83 is fixedly connected to the axis of the rear end face of the rotating disc 73, a gear cavity 85 is disposed in the rear wall of the reciprocating cavity 72, the transmission rotating shaft 83 extends backwards into the gear cavity 85 and is fixedly disposed with a transmission bevel gear 84, a driven bevel gear 86 engaged with the transmission bevel gear 84 is rotatably disposed in the gear cavity 85 close to the crushing cavity 59, a reciprocating motor 87 is fixedly disposed in one side wall of the gear cavity 85 on the left and right sides close to the crushing cavity 59, the left and right driven bevel gears 86 are respectively connected to the left and right ends of the reciprocating motor 87.

Advantageously, the grinding mechanism 105 comprises a grinding rotating shaft 52 rotatably disposed between the left and right walls of the grinding chamber 56 and symmetrically arranged in front and back, a grinding wheel 55 is fixedly connected to the outer circumferential end face of the grinding rotating shaft 52, an engaging chamber 54 is disposed in the right wall of the grinding chamber 56, the right end of the grinding rotating shaft 52 on the front and back sides extends into the engaging chamber 54 and is fixedly connected with an engaging wheel 53 capable of being engaged by gears, an energy supply motor 75 is fixedly disposed in the right wall on the front side of the engaging chamber 54, and the engaging wheel 53 on the front side is dynamically connected to the energy supply motor 75.

Beneficially, energy supply motor 75 right side is equipped with pulley chamber 50, the antetheca rotates and is equipped with driving pulley 51 in pulley chamber 50, driving pulley 51 power connect in energy supply motor 75, pulley chamber 50 rear side intercommunication is equipped with the belt chamber 81 of vertical direction, pulley chamber 50 back wall just is located belt chamber 81 upside rotates and is equipped with driving pulley 77, driving pulley 77 axle center fixedly connected with supports pivot 78, driving pulley 77 excircle terminal surface right side with around being equipped with belt 76 between the driving pulley 51, the rotation of lower wall is equipped with from driving wheel 80 in the belt chamber 81, from driving wheel 80 with driving pulley 77 excircle terminal surface left side is around being equipped with conveyer 79.

Advantageously, the conveying mechanism 106 includes a conveying shaft 44 which is symmetrical in front and back and is rotatably disposed on the left and right walls in the conveying cavity 46, the right end face of the front side conveying shaft 44 extends into the belt cavity 81 and is fixedly connected to the axis of the left end face of the driven wheel 80, a conveying belt 69 is wound between the front side conveying roller 45 and the rear side conveying roller 45, the rear wall of the stone accumulating cavity 47 is provided with a stone outlet channel 39 in a communicating manner, and the conveying belt 69 conveys the crushed ore backwards into the stone outlet channel 39.

Beneficially, the discharging mechanism 107 includes a discharging connecting pipe 62 which is communicated with and arranged in the moving block 70, the upper side of the discharging connecting pipe 62 is communicated with a stone conveying channel 40 with a telescopic length, the rear side of the stone conveying channel 40 is communicated with the stone discharging channel 39, the lower side of the discharging connecting pipe 62 is communicated with a material conveying funnel 42 with a downward opening for discharging, the center of the moving block 70 is in threaded connection with a threaded connecting rod 41, a conveying motor 43 is fixedly arranged in the right wall of the ore discharging cavity 38, the right end of the threaded connecting rod 41 is in power connection with the conveying motor 43, the end faces of the left and right walls of the ore discharging cavity 38 are communicated and are provided with moving cavities 66 in bilateral symmetry, a pressing block 63 which can move left and right is arranged in the moving cavity 66, an electromagnetic block 64 is fixedly arranged at one end of the pressing block 63 which is far away from the ore discharging cavity 38, and an electromagnetic switch 67 is, a spring 65 is fixedly connected between the electromagnetic switch 67 and the pressing block 63.

The steps of use of a mineral breaker having a screening and breaking loading function herein are described in detail below with reference to figures 1 to 8: in the initial state, the upper, middle and lower push plates 16 are at the left limit position, the upper, middle and lower output flappers 12 are vertically downward, the moving block 70 is at the right limit position, and the left and right impact plates 71 are at the side close to the crushing chamber 59.

During operation, the excavated ore is placed in the working chamber 15, at this time, the driving motor 27 is started to drive the driving wheel 33 to rotate, the driving wheel 33 drives the driving wheels 33 on each side to rotate through the transmission chain 88, the driving wheel 33 drives the rotating shaft 32 to rotate to drive the eccentric rotary drum 31 to rotate, the eccentric rotary drum 31 deviates from the rotating center and is abutted against the lower end surface of the vibration box 30, at this time, the eccentric rotary drum 31 drives the vibration box 30 to vibrate at high frequency up and down, at this time, the ore with moderate size and the smaller ore are screened by the stone filter plate 60 to fall downwards to the position of the middle working chamber 15 due to the vibration of the vibration box 30, and at the same time, the smaller ore continuously falls into the lower working chamber 15 through the screening of the stone filter plate 61, so as to achieve the effect of screening the ore, meanwhile, the driving motor 27 drives the left driving sprocket 26 to rotate, and, the driven chain wheel 22 drives the threaded rod 17 to rotate, the threaded rod 17 drives the moving rod 18 to slowly move rightwards through threaded connection, at the moment, the moving rod 18 drives the push plate 16 to move rightwards and push ores to move rightwards, at the moment, the upper push plate 16 pushes large ores staying at the upper end of the stone filter plate 60 to move rightwards and abut against the upper output baffle plate 12 to rotate anticlockwise, at the moment, the large ores fall into the stone channel 19, the middle push plate 16 moves rightwards and pushes medium-shaped ores on the upper end face of the stone filter plate 61 to move rightwards and push the middle output baffle plate 12 to rotate anticlockwise, at the moment, the medium-shaped ores fall into the fragment channel 29, the lower push plate 16 moves rightwards and pushes small ore crushed sands on the upper end face of the lower side of the vibration box 30 to move rightwards and fall into, at this time, the large ore slides down from the stone passage 19 to the crushing chamber 59, the reciprocating motor 87 is started to drive the driven bevel gear 86 to rotate, the driven bevel gear 86 drives the transmission bevel gear 84 to rotate through gear engagement, the transmission bevel gear 84 drives the rotary disc 73 to rotate through the transmission rotary shaft 83, the rotary disc 73 drives the impact plate 71 to reciprocate left and right through the driving rotary connecting rod 74, at this time, the left and right impact plates 71 achieve the hammering effect of rapidly reciprocating to the middle crushing chamber 59 for crushing the large ore, then the ore crushed into a medium shape falls down into the stone passage 57 through the screening of the stone filtering plate 58 and finally falls into the crushing chamber 56, while the medium ore in the other side fragment passage 29 falls down along the fragment passage 29 and also falls into the crushing wheel 55, at this time, the energy supply motor 75 is started to drive the front engaging wheel 53 to rotate, the engaging wheel 53 drives the rear engaging wheel 53 to rotate through gear engagement, at the moment, the meshing wheels 53 at the front side and the rear side drive the grinding wheels 55 to rotate towards the center direction, so as to achieve the effect of grinding ores, then the ores ground into small crushed pieces fall into the stone outlet channel 48 through the screening of the stone crushing filter plate 49 and are finally accumulated on the upper end surface of the conveyor belt 69 in the stone accumulation cavity 47, small crushed ore in the stone crushing channel 28 at the other side also falls onto the upper end surface of the conveyor belt 69, meanwhile, the energy supply motor 75 drives the driving belt pulley 51 to rotate, the driving belt pulley 51 drives the power belt pulley 77 to rotate through the belt 76, the power belt pulley 77 drives the driven wheel 80 to rotate through the conveyor belt 79, the driven wheel 80 drives the front side conveying roller 45 to rotate through driving the conveying shaft 44, the front side conveying roller 45 is driven by the conveyor belt 69 and the rear side conveying roller 45, so as to achieve the effect of conveying small crushed stones to the right by the, and is transported to the discharging connecting pipe 62 through the stone conveying channel 40 and is discharged downwards through the material conveying funnel 42, at this time, the conveying motor 43 is started to drive the threaded connecting rod 41 to rotate, the threaded connecting rod 41 drives the moving block 70 to move leftwards through gear engagement, when the moving block 70 moves to the left limit, the left end surface of the moving block 70 butts against the left pressing block 63 and enables the left pressing block to move leftwards by overcoming the elasticity of the left spring 65, at this time, the pressing block 63 drives the left electromagnetic block 64 to move leftwards, and finally, the left electromagnetic block 64 butts against the left electromagnetic switch 67 and controls the conveying motor 43 to rotate reversely to start, when the moving block 70 moves rightwards to the right limit, the right pressing block 63 and the right electromagnetic switch 67 touch and control the conveying motor 43 to rotate forwards again to start, so as to output crushed ore back and forth in a left-and-right reciprocating manner, the conveying motor 43 drives the moving block 70 to return to the initial position and then stops, the energy supply motor 75 stops rotating at this time, the reciprocating motor 87 drives the left and right side impact plates 71 to return to the initial position and then stops, and at this time, the ore crushing work and the output loading work are completed.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. A mineral breaker with screening and crushing loading function, includes the organism, its characterized in that: the machine body is internally provided with a working chamber with an upward opening, the working chamber is internally provided with a vibrating box with an upward opening and capable of slightly moving up and down, the upper trisection and the lower trisection of the front wall and the rear wall of the vibrating box are fixedly provided with two stone filtering plates and stone filtering plates with different specifications, the stone filtering plates and the stone filtering plates trisect the working chamber, the left walls of the upper, middle and lower trisections of the working chamber are internally provided with propelling chambers with the same size, the propelling chambers are internally provided with propelling mechanisms with the same three mechanisms, the left wall of the propelling chamber is internally provided with a chain wheel chamber, the chain wheel chamber is internally provided with a transmission mechanism, the transmission mechanism provides power for the propelling mechanisms, the lower side of the working chamber is communicated with the vibrating chamber, the vibrating chamber is internally provided with the vibrating mechanism, the right side of the upper side of the working chamber is communicated with a, the crushing cavity is characterized in that the front wall and the rear wall of the crushing cavity are communicated and symmetrically provided with reciprocating cavities, the reciprocating cavities on the front side and the rear side are internally provided with reciprocating mechanisms which have the same mechanism and are symmetrical relative to the crushing cavity, a stone filter plate with the same specification as the stone filter plate is fixedly arranged between the front wall, the rear wall and the front wall and between the front wall and the rear wall of the lower side of the crushing cavity, the lower side of the stone filter plate is provided with a stone channel communicated with the crushing cavity, the lower side of the stone channel is communicated with a crushing wheel, the left side of the upper wall of the crushing wheel is communicated with the right wall of the working cavity on the middle side, the crushing cavity is internally provided with a crushing mechanism, the lower side of the crushing cavity is fixedly provided with a crushed stone filter plate with the same specification as the crushed stone filter plate, the lower side of the crushed stone filter plate is provided with a stone, the ore deposit conveying device is characterized in that a conveying cavity is formed in the lower side of the inner side of the ore deposit cavity in a communicating mode, a conveying mechanism is arranged in the conveying cavity, an ore discharging channel is formed in the right wall of the ore deposit cavity in a communicating mode, an ore discharging cavity with a downward opening is formed in the lower wall of the conveying cavity, a moving block capable of moving left and right is arranged in the ore discharging cavity, and a discharging mechanism is arranged in the moving block and is used for outputting crushed ores to be.

2. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: the upper side working chamber and stone channel intercommunication department and with the medial side working chamber with fragment channel intercommunication department and downside the working chamber with rubble channel intercommunication department is equipped with three equal and can control the output baffle that overturns, output baffle up end fixedly connected with cylindric rotation connecting rod, the rotation connecting rod rotate connect in the supporting shoe, the supporting shoe up end fixed connection in three sides about the right-hand member face of vibrations case.

3. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: the pushing mechanism comprises a moving rod which is arranged in the pushing cavity and can move left and right, a threaded rod is connected with the inner circular surface of the moving rod in a threaded manner, and a push plate arranged on the left wall in the working cavity is fixedly connected to the right end surface of the moving rod.

4. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: the transmission mechanism comprises three driven sprockets with the same size and rotatably arranged in a sprocket cavity, the left end face of the threaded rod extends to the sprocket cavity and is fixedly connected to the three sides of the sprocket cavity respectively, a driving sprocket is rotatably arranged on the lower wall of the sprocket cavity, the driving sprocket and the driven sprockets are wound with the same chain, a driving motor is fixedly arranged on the lower side of the inner wall of the sprocket cavity, and the driving sprocket is in power connection with the driving motor.

5. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: the vibrations mechanism include the mechanism the same and transverse array arrange in vibrations intracavity and rotate and locate the axis of rotation between the two walls of left and right sides, the outer terminal surface of axis of rotation is fixed and is equipped with eccentric rotary drum, eccentric rotary drum up end with terminal surface offsets under the vibrations case, axis of rotation left end face extends to transmission intracavity and fixedly connected with action wheel, each all around being equipped with drive chain between the action wheel, the well side action wheel left end power connect in driving motor.

6. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: the reciprocating mechanism comprises rotary tables which are rotatably arranged on the left side and the right side of the rear wall in the reciprocating cavity, the rotary tables on the left side and the right side are hinged with a rotary connecting rod, a striking plate capable of moving left and right is arranged at one side of the reciprocating cavity close to the crushing cavity, one end of the rotating connecting rod at the left and right sides close to the crushing cavity is hinged with the end surface of the striking plate far away from the crushing cavity, the axle center of the back end surface of the turntable is fixedly connected with a transmission rotating shaft, a gear cavity is arranged in the back wall of the reciprocating cavity, the transmission rotating shaft extends to the rear of the gear cavity and is fixedly provided with a transmission bevel gear, the end face of the crushing cavity, which is close to the gear cavity, in the gear cavity is rotatably provided with a driven bevel gear meshed with the transmission bevel gear, the gear cavity is close to one side wall of the crushing cavity, the inner parts of the left side and the right side are fixedly provided with a reciprocating motor, and the driven bevel gears are respectively in power connection with the left end and the right end of the reciprocating motor.

7. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: pulverize the mechanism and locate including rotating pulverize the chamber about between the two walls and the crushing pivot of front and back symmetry, pulverize pivot excircle terminal surface fixedly connected with and pulverize the wheel, pulverize the intracavity right side and be equipped with the meshing chamber in the wall, both sides around it extends to pulverize pivot right-hand member meshing intracavity and fixedly connected with can gear engagement's meshing wheel, meshing chamber front side right side wall internal fixation is equipped with energy supply motor, the front side meshing wheel power connect in energy supply motor.

8. A mineral breaker having a screening and breaking loading function in accordance with claim 7 wherein: energy supply motor right side is equipped with the band pulley chamber, the antetheca rotates and is equipped with driving pulley in the band pulley intracavity, driving pulley power connect in the energy supply motor, band pulley chamber rear side intercommunication is equipped with the belt chamber of vertical direction, band pulley chamber back wall just is located the rotation of belt chamber upside is equipped with power pulley, power pulley axle center fixedly connected with supports the pivot, power pulley excircle terminal surface right side with around being equipped with the belt between the driving pulley, the rotation of belt intracavity lower wall is equipped with from the driving wheel, from the driving wheel with power pulley excircle terminal surface left side is around being equipped with conveyer.

9. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: conveying mechanism includes the front and back symmetry and rotates and locates the conveying axle of conveying intracavity left and right sides wall, front side conveying axle right-hand member face extends to belt intracavity and fixed connection in from driving wheel left end face axle center, both sides around being equipped with the conveyer belt between the conveying drum, amassing stone cavity back wall intercommunication is equipped with out the stone passageway, the conveyer belt with the ore after grinding conveying backward in the stone passageway.

10. A mineral breaker having a screening and breaking loading function in accordance with claim 1 wherein: discharge mechanism locates including the intercommunication the ejection of compact in the removal piece is managed even, the intercommunication of ejection of compact even pipe upside is equipped with the defeated stone passageway of scalable length, defeated stone passageway rear side with go out stone passageway intercommunication, the intercommunication of ejection of compact even pipe downside is equipped with the decurrent conveying hopper of opening and is used for the ejection of compact, removal piece central thread is connected with the screw thread connecting rod, the fixed conveyor motor that is equipped with in the chamber right side wall of ore removal, screw thread connecting rod right-hand member power connect in conveyor motor, both sides terminal surface intercommunication and bilateral symmetry are equipped with the removal chamber about the chamber of ore removal, it is equipped with the pressure piece that removes to remove the intracavity, keep away from to press the piece the fixed electromagnetic block that is equipped with in chamber one end of ore removal, remove the chamber and keep away from the fixed electromagnetic switch that is equipped with in chamber terminal surface of ore.