CN113304804A

CN113304804A - Mineral secondary processing equipment

Info

Publication number: CN113304804A
Application number: CN202110603145.0A
Authority: CN
Inventors: 付玉荣
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-05-31
Filing date: 2021-05-31
Publication date: 2021-08-27

Abstract

The invention relates to the field of secondary processing of minerals, in particular to secondary processing equipment for minerals. Can be used for secondary processing of minerals. Including crushing unit, pan feeding subassembly, secondary treatment subassembly, driving belt three, driving belt one, driving belt two, crushing unit is connected with the pan feeding subassembly, and manual the inner manual bull stick of rotating, and then drive inner screw thread sleeve pipe motion through inner manual bull stick, and then drive screw thread sleeve pipe hinge bar motion through inner screw thread sleeve pipe, and then drive articulated connecting rod motion through screw thread sleeve pipe hinge bar, and then drive the motion of dust removal flabellum through articulated connecting rod, and then make dust removal flabellum change air flow rate.

Description

Mineral secondary processing equipment

Technical Field

The invention relates to the field of secondary processing of minerals, in particular to secondary processing equipment for minerals.

Background

Mineral secondary processing equipment is a common equipment in the field of mineral secondary processing, but the function of general mineral secondary processing equipment is single.

Disclosure of Invention

The invention aims to provide secondary mineral processing equipment which can be used for secondary mineral processing equipment.

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

the utility model provides a mineral secondary processing equipment, includes crushing unit, pan feeding subassembly, secondary treatment subassembly, driving belt three, driving belt one, driving belt two, crushing unit is connected with the pan feeding subassembly, and the pan feeding subassembly is connected with the secondary treatment subassembly, and driving belt three is connected with the secondary treatment subassembly, and driving belt one is connected with pan feeding subassembly, secondary treatment subassembly, and driving belt two is connected with crushing unit and pan feeding subassembly.

As a further optimization of the technical scheme, the invention relates to secondary mineral processing equipment, which comprises a crushing outer frame, a crankshaft, a driving rotating rod, a driving block, a first driving block connecting rod, a first driving connecting rod, a second driving connecting rod, a crushing sliding rod, a crankshaft limiting boss, a crushing vibration boss, a first inner end spring, a second inner end spring, a sealing ring, a first inner end limiting frame, a first inner end clamping groove, a first inner end clamping rod and a first inner end clamping rod pushing spring, wherein the crankshaft is rotationally connected with the crushing outer frame, the crankshaft limiting boss is fixedly connected with the crankshaft, the driving rotating rod is rotationally connected with the crushing outer frame, the driving block is in matched connection with the driving rotating rod, the first inner end clamping groove is arranged on the driving rotating rod and is in sliding connection with the driving block, the first inner end clamping rod pushing spring is arranged between the first inner end clamping rod and the driving block, the first inner end clamping rod is in matched connection with the first inner end clamping groove, the first driving block is rotationally connected with the driving block, one end of a driving connecting rod is hinged with a driving block connecting rod I, the other end of the driving connecting rod I is hinged with a driving connecting rod II, the other end of the driving connecting rod II is hinged with a crushing slide rod, the crushing slide rod is connected with a crushing vibration boss in a sliding mode, the crushing vibration boss is connected with an inner limiting frame in a sliding mode, the inner limiting frame is fixedly connected with a crushing outer frame, an inner spring I, an inner spring II is arranged at two ends of the crushing slide rod respectively, a sealing ring is fixedly connected with the crushing vibration boss, the sealing ring is connected with the crushing slide rod in a sliding mode, a crankshaft is rotatably connected with one driving connecting rod, a plurality of crankshaft limiting bosses are arranged, and the driving connecting rod I is arranged between two adjacent driving connecting rods I.

As a further optimization of the technical scheme, the invention relates to mineral secondary processing equipment, which comprises a feeding outer frame, a feeding grid plate, a grid, an arc-shaped limiting chute, a driving boss, a driving slide rod, a side wall chute, an inner slide column, an inner push spring II, an eccentric driving disk, a driving belt wheel A, an inner slide rod I, an inner clamping rod II and an inner clamping groove II, wherein the feeding grid plate is rotatably connected with the feeding outer frame, the grid is arranged on the feeding grid plate, a plurality of grids are arranged on the grid, the arc-shaped limiting chute is arranged on the feeding outer frame, the driving boss is slidably connected with the arc-shaped limiting chute, the driving boss is fixedly connected with the feeding grid plate, the driving boss is slidably connected with the driving slide rod, the driving slide rod is slidably connected with the side wall chute, the side wall chute is arranged on the feeding outer frame, the inner slide column is arranged at the inner end of the side wall chute, the driving slide bar is connected with the inner sliding columns in a sliding mode, two inner pushing springs are arranged, the two inner pushing springs are connected with the inner sliding columns in a sleeved mode, the driving slide bar is arranged between the two inner pushing springs, the eccentric driving disc is connected with the feeding outer frame in a rotating mode, the driving belt wheel A is fixedly connected with the eccentric driving disc, the inner slider is connected with the eccentric driving disc in a sliding mode, the inner slider is connected with the driving slide bar in a sliding mode, the inner clamping rod is connected with the inner slider in a sliding mode, the inner clamping rod is connected with the inner clamping groove II in a matched mode, the inner clamping groove II is arranged on the eccentric driving disc, the inner clamping rod pushing springs are arranged between the two inner clamping rods, the crushing outer frame is fixedly connected with the feeding outer frame, and the driving belt II is connected between the crankshaft and the driving belt wheel A.

As a further optimization of the technical scheme, the invention relates to mineral secondary processing equipment, which comprises a secondary processing outer frame, a dust removal outer frame, a bevel gear rod I, a bevel gear I, an inner end manual rotating rod, an inner end carrier belt, a dust removal port, an inner end shaft I, an inner end shaft II, an inner end roller I, an inner end roller II, an inner end sleeve I, an inner end fixing boss, a discharge port, an inner end threaded sleeve, a threaded sleeve hinged rod, a hinged connecting rod, a dust removal fan blade and a bevel gear II, wherein the secondary processing outer frame is fixedly connected with the dust removal outer frame, the bevel gear rod I is rotatably connected with the dust removal outer frame, the bevel gear I is fixedly connected with the bevel gear rod I, the bevel gear I is in meshing transmission with the bevel gear II, the bevel gear II is fixedly connected with the inner end sleeve I, the inner end sleeve I is rotatably connected with the dust removal outer frame, the inner end fixing boss is fixedly connected with the inner end sleeve I, the inner end manual rotating rod is rotatably connected with the inner end manual rotating rod, the discharge port and the dust removal port are both arranged on the secondary treatment outer frame, the discharge port and the dust removal port are respectively arranged on the same side of the secondary treatment outer frame, an inner end threaded sleeve is in threaded connection with an inner end manual rotating rod, the inner end threaded sleeve is in hinged connection with a threaded sleeve hinge rod, the threaded sleeve hinge rod is in hinged connection with a hinge connecting rod, the hinge connecting rod is fixedly connected with a dust removal fan blade, the dust removal fan blade is in rotary connection with an inner end sleeve, an inner end shaft I and an inner end shaft II are both in rotary connection with the secondary treatment outer frame, the inner end shaft I and the inner end shaft II are respectively and fixedly connected with an inner end shaft I and an inner end shaft II, an inner end carrying belt is connected to the inner end shaft I and the inner end shaft II, a transmission belt III is connected between the inner end shaft I and a bevel gear rod I, the transmission belt I is connected between the inner end shaft I and a driving belt wheel A, and the secondary treatment outer frame is fixedly connected with the feeding outer frame.

As a further optimization of the technical scheme, the crankshaft of the mineral secondary processing equipment is provided with an input motor A.

The mineral secondary processing equipment has the beneficial effects that:

according to the mineral secondary processing equipment, the inner-end manual rotating rod is manually rotated, the inner-end manual rotating rod drives the inner-end threaded sleeve to move, the inner-end threaded sleeve drives the threaded sleeve hinge rod to move, the threaded sleeve hinge rod drives the hinge connecting rod to move, the hinge connecting rod drives the dust removing fan blades to move, and the dust removing fan blades change the air flow rate.

Drawings

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

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic view of the shredder assembly 1 of the present invention;

FIG. 4 is a second schematic structural view of the size reduction assembly 1 of the present invention;

FIG. 5 is a third schematic structural view of the size reduction assembly 1 of the present invention;

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

FIG. 7 is a schematic structural view of a feeding assembly 2 according to the present invention;

FIG. 8 is a schematic structural view III of the feeding assembly 2 of the present invention;

FIG. 9 is a schematic view of the second processing assembly 3 according to the present invention;

FIG. 10 is a schematic structural view of a secondary processing assembly 3 of the present invention;

FIG. 11 is a third schematic structural view of the secondary processing assembly 3 of the present invention.

In the figure: a crushing assembly 1; crushing the outer frame 1-1; a crankshaft 1-2; driving a rotating rod 1-3; driving blocks 1-4; a first driving block connecting rod 1-5; 1-6 of a driving connecting rod I; a second driving connecting rod 1-7; crushing slide bars 1-8; 1-9 parts of crankshaft limiting boss; 1-10 parts of crushing and vibrating bosses; the inner end springs are 1-11; a second inner end spring 1-12; 1-13 parts of a sealing ring; inner end limiting frames 1-14; a first clamping groove at the inner end is 1-15; the inner end clamping rod I is 1-16; the inner end clamping rod pushes the spring 1-17; a feeding assembly 2; feeding an outer frame 2-1; feeding a grid plate 2-2; 2-3 of grids; 2-4 of an arc-shaped limiting sliding chute; 2-5 of a driving boss; driving the slide bar 2-6; 2-7 side wall chutes; 2-8 of inner end sliding columns; the inner end pushes a second spring 2-9; 2-10 parts of an eccentric driving disc; a drive pulley A2-11; 2-12 inner end sliders I; the inner end is clamped by a second 2-13 rod; the inner end clamping rod pushes a second spring 2-14; a second inner end clamping groove 2-15; a secondary treatment component 3; performing secondary treatment on the outer frame 3-1; 3-2 of a dedusting outer frame; 3-3 parts of a bevel gear rod I; 3-4 parts of a first bevel gear; the inner end of the manual rotating rod is 3-5; inner end carrier belts 3-6; 3-7 parts of a dust removal port; 3-8 parts of an inner end shaft I; 3-9 parts of an inner end shaft II; the inner end rollers are 3-10; inner end rollers 3-11; 3-12 parts of an inner end sleeve; the inner end is fixed with a boss 3-13; 3-14 parts of a discharge port; inner end thread sleeves 3-15; threaded bushing hinge rods 3-16; hinge links 3-17; 3-18 parts of dust removing fan blades; 3-19 parts of a second bevel gear; a third transmission belt 4; a first transmission belt 5; and a second transmission belt 6.

Detailed Description

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

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

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 11, and a mineral secondary processing device includes a crushing assembly 1, a feeding assembly 2, a secondary processing assembly 3, a transmission belt three 4, a transmission belt one 5, and a transmission belt two 6, wherein the crushing assembly 1 is connected with the feeding assembly 2, the feeding assembly 2 is connected with the secondary processing assembly 3, the transmission belt three 4 is connected with the secondary processing assembly 3, the transmission belt one 5 is connected with the feeding assembly 2 and the secondary processing assembly 3, and the transmission belt two 6 is connected with the crushing assembly 1 and the feeding assembly 2.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-11, and the embodiment further describes the first embodiment, wherein the crushing assembly 1 comprises a crushing outer frame 1-1, a crankshaft 1-2, a driving rotating rod 1-3, a driving block 1-4, a driving block connecting rod 1-5, a driving connecting rod 1-6, a driving connecting rod two 1-7, a crushing sliding rod 1-8, a crankshaft limit boss 1-9, a crushing vibration boss 1-10, an inner end spring 1-11, an inner end spring two 1-12, a sealing ring 1-13, an inner end limit frame 1-14, an inner end clamping groove 1-15, an inner end clamping rod one 1-16, and an inner end clamping rod push spring one 1-17, the crankshaft 1-2 is rotatably connected with the crushing outer frame 1-1, the crankshaft limit boss 1-9 is fixedly connected with the crankshaft 1-2, the driving rotating rod 1-3 is rotatably connected with the crushing outer frame 1-1, the driving block 1-4 is connected with the driving rotating rod 1-3 in a matching way, the inner end clamping groove 1-15 is arranged on the driving rotating rod 1-3, the inner end clamping rod 1-16 is connected with the driving block 1-4 in a sliding way, the inner end clamping rod push spring 1-17 is arranged between the inner end clamping rod 1-16 and the driving block 1-4, the inner end clamping rod 1-16 is connected with the inner end clamping groove 1-15 in a matching way, the driving block connecting rod 1-5 is rotatably connected with the driving block 1-4, one end of the driving connecting rod 1-6 is hinged with the driving block connecting rod 1-5, the other end of the driving connecting rod 1-6 is hinged with the driving connecting rod two 1-7, the other end of the driving connecting rod two 1-7 is hinged with the crushing sliding rod 1-8, the crushing and vibrating mechanism comprises a crushing slide rod 1-8, crushing and vibrating bosses 1-10, inner end limiting frames 1-14, crushing outer frames 1-1, inner end springs 1-11 and inner end springs 1-12, wherein the inner end springs 1-12 are arranged at two ends of the crushing slide rod 1-8 respectively, sealing rings 1-13 are fixedly connected with the crushing and vibrating bosses 1-10, the sealing rings 1-13 are connected with the crushing slide rod 1-8 in a sliding mode, a crankshaft 1-2 is rotatably connected with driving connecting rods 1-6, a plurality of crankshaft limiting bosses 1-9 are arranged, and driving connecting rods 1-6 are arranged between two adjacent driving connecting rods 1-6.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-11, and the embodiment further describes the first embodiment, where the feeding assembly 2 includes a feeding outer frame 2-1, a feeding grid plate 2-2, a grid 2-3, an arc-shaped limiting chute 2-4, a driving boss 2-5, a driving slide bar 2-6, a side wall chute 2-7, an inner end slide column 2-8, an inner end push spring two 2-9, an eccentric driving disc 2-10, a driving pulley a2-11, an inner end slide first 2-12, an inner end clamping bar two 2-13, an inner end clamping bar push spring two 2-14, and an inner end clamping bar two 2-15, the feeding grid plate 2-2 is rotatably connected with the feeding outer frame 2-1, the grid 2-3 is disposed on the feeding grid plate 2-2, and a plurality of grids 2-3 are disposed, an arc-shaped limiting chute 2-4 is arranged on a feeding outer frame 2-1, a driving boss 2-5 is connected with the arc-shaped limiting chute 2-4 in a sliding manner, the driving boss 2-5 is fixedly connected with a feeding grid plate 2-2, the driving boss 2-5 is connected with a driving slide bar 2-6 in a sliding manner, the driving slide bar 2-6 is connected with a side wall chute 2-7 in a sliding manner, a side wall chute 2-7 is arranged on the feeding outer frame 2-1, an inner end slide post 2-8 is arranged at the inner end of the side wall chute 2-7, the driving slide bar 2-6 is connected with an inner end slide post 2-8 in a sliding manner, two inner end push springs 2-9 are arranged, the two inner end push springs 2-9 are connected with the inner end slide post 2-8 in a sleeved manner, and the driving slide bar 2-6 is arranged between the two inner end push springs 2-9, the eccentric driving disc 2-10 is rotatably connected with the feeding outer frame 2-1, the driving belt wheel A2-11 is fixedly connected with the eccentric driving disc 2-10, the inner end slider I2-12 is slidably connected with the driving slide bar 2-6, the inner end clamping bar II 2-13 is slidably connected with the inner end slider I2-12, the inner end clamping bar II 2-13 is in matched connection with the inner end clamping groove II 2-15, the inner end clamping groove II 2-15 is arranged on the eccentric driving disc 2-10, the inner end clamping bar push spring II 2-14 is arranged between the two inner end clamping bars II 2-13, the crushing outer frame 1-1 is fixedly connected with the feeding outer frame 2-1, and the driving belt wheel A2-11 is connected between the crankshaft 1-2 and the driving belt wheel A2-11.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-11, and the embodiment further describes the first embodiment, the secondary processing assembly 3 includes a secondary processing outer frame 3-1, a dust removing outer frame 3-2, a first bevel gear rod 3-3, a first bevel gear 3-4, an inner end manual rotating rod 3-5, an inner end carrier belt 3-6, a dust removing port 3-7, a first inner end shaft 3-8, a second inner end shaft 3-9, a first inner end roller 3-10, a second inner end roller 3-11, a first inner end sleeve 3-12, an inner end fixing boss 3-13, a discharge port 3-14, a inner end threaded sleeve 3-15, a threaded sleeve hinge rod 3-16, a hinge connecting rod 3-17, dust removing fan blades 3-18, and a second bevel gear 3-19, the secondary processing outer frame 3-1 is fixedly connected with the dust removing outer frame 3-2, a bevel gear rod I3-3 is rotationally connected with a dedusting outer frame 3-2, a bevel gear I3-4 is fixedly connected with the bevel gear rod I3-3, the bevel gear I3-4 is in meshed transmission with a bevel gear II 3-19, the bevel gear II 3-19 is fixedly connected with an inner end sleeve I3-12, the inner end sleeve I3-12 is rotationally connected with the dedusting outer frame 3-2, an inner end fixing boss 3-13 is fixedly connected with the inner end sleeve I3-12, an inner end manual rotating rod 3-5 is rotationally connected with an inner end manual rotating rod 3-5, a discharge port 3-14 and a dedusting port 3-7 are both arranged on a secondary processing outer frame 3-1, the discharge port 3-14 and the dedusting port 3-7 are respectively arranged on the same side of the secondary processing outer frame 3-1, an inner end threaded sleeve 3-15 is in threaded connection with the inner end manual rotating rod 3-5, the inner end threaded sleeve 3-15 is hinged with a threaded sleeve hinge rod 3-16, the threaded sleeve hinge rod 3-16 is hinged with a hinge connecting rod 3-17, the hinge connecting rod 3-17 is fixedly connected with a dust removing fan blade 3-18, the dust removing fan blade 3-18 is rotatably connected with the inner end sleeve I3-12, the inner end shaft I3-8 and the inner end shaft II 3-9 are rotatably connected with the secondary processing outer frame 3-1, the inner end shaft I3-8 and the inner end shaft II 3-9 are respectively fixedly connected with the inner end shaft I3-8 and the inner end shaft II 3-9, the inner end carrier belt 3-6 is connected with the inner end shaft I3-8 and the inner end shaft II 3-9, the transmission belt III 4 is connected between the inner end shaft I3-8 and the bevel gear rod I3-3, the transmission belt I5 is connected between the inner end shaft I3-8 and the driving belt wheel A2-11, the secondary treatment outer frame 3-1 is fixedly connected with the feeding outer frame 2-1;

the inner end shaft I3-8 moves to drive the bevel gear rod I3-3 to move through the transmission belt III 4, further drive the bevel gear I3-4 to move through the bevel gear rod I3-3, further drive the bevel gear II 3-19 to move through the bevel gear I3-4, further drive the inner end sleeve I3-12 to move through the bevel gear II 3-19, further drive the dust removal fan blades 3-18 to move through the inner end sleeve I3-12, further drive the air to flow through the dust removal fan blades 3-18, and further discharge dust generated in the ore crushing process through the dust removal port 3-7; meanwhile, the inner-end manual rotating rod 3-5 is manually rotated, the inner-end threaded sleeve 3-15 is driven to move through the inner-end manual rotating rod 3-5, the threaded sleeve hinge rod 3-16 is driven to move through the inner-end threaded sleeve 3-15, the hinged connecting rod 3-17 is driven to move through the threaded sleeve hinge rod 3-16, the dust removing fan blade 3-18 is driven to move through the hinged connecting rod 3-17, and the air flow rate of the dust removing fan blade 3-18 is changed.

The fifth concrete implementation mode:

the present embodiment will be described with reference to fig. 1 to 11, and the present embodiment further describes the first embodiment, in which the crankshaft 1 to 2 is provided with an input motor a.

The invention relates to mineral secondary processing equipment, which has the working principle that:

when the crushing device is used, the input motor A matched with the crankshaft 1-2 is started, the crankshaft 1-2 is further driven to rotate, the driving connecting rod I1-6 is further driven to move through the crankshaft 1-2, the driving connecting rod II 1-7 is further driven to move through the driving connecting rod I1-6, the crushing slide rod 1-8 is further driven to move through the driving connecting rod II 1-7, the inner end spring I1-11 and the inner end spring II 1-12 are further driven to move through the crushing slide rod 1-8, the crushing vibration boss 1-10 is further driven to move through the inner end spring I1-11 and the inner end spring II 1-12, and the crushing vibration boss 1-10 is further contacted with minerals, so that the minerals are crushed; meanwhile, the driving rotating rod 1-3 is rotated manually, and then the driving rotating rod 1-3 drives the inner end clamping groove 1-15 to move, further drives the inner end clamping rod I1-16 to move through the inner end clamping groove I1-15, the driving blocks 1-4 are driven to move by the inner end clamping rods 1-16, the driving blocks 1-4 are driven to move by the driving blocks 1-5, further drives the driving connecting rods I1-6 to move through the driving block connecting rods I1-5, so that the hinging positions of the driving connecting rods 1-6 and the driving block connecting rods 1-5 are changed, so that the stroke of the vertical reciprocating motion of the crushing vibration boss 1-10 driven by the crankshaft 1-2 and the transmission relationship disclosed above is changed, and the adjustment of the ore crushing degree is realized; ore to be processed is placed on the feeding grid plate 2-2, meanwhile, the crankshaft 1-2 drives the driving belt wheel A2-11 to move through the driving belt II 6, further drives the eccentric driving disc 2-10 to move through the driving belt wheel A2-11, further drives the inner end slider I2-12 to move through the eccentric driving disc 2-10, further drives the driving slide bar 2-6 to move through the inner end slider I2-12, further drives the driving boss 2-5 to move through the driving slide bar 2-6, further enables the driving boss 2-5 to slide along the arc limiting chute 2-4, simultaneously drives the feeding grid plate 2-2 to move through the driving boss 2-5, further enables the ore on the feeding grid plate 2-2 to fall into the feeding outer frame 2-1, thereby facilitating the next processing; meanwhile, in order to adapt to ores of different specifications, the inner end slider I2-12 and the eccentric driving disk 2-10 are relatively slid, so that the motion track of the inner end slider I2-12 is changed, the motion amplitude of the driving slide rod 2-6 is changed, and the motion track of the feeding grid plate 2-2 is changed; meanwhile, the driving belt wheel A2-11 rotates to drive the transmission belt wheel 5 to move, further the transmission belt wheel 5 drives the inner end shaft I3-8 to rotate, further the inner end shaft I3-8 drives the inner end roller I3-10 to move, further the inner end roller I3-10 drives the inner end carrier belt 3-6 to move, further the inner end carrier belt 3-6 carries ore to move towards the right side, simultaneously the crushed ore is discharged through the discharge port 3-14 by crushing the crushing vibration boss 1-10, simultaneously, the inner end shaft I3-8 moves to drive the bevel gear rod I3-3 to move through the transmission belt wheel III 4, further the bevel gear rod I3-3 drives the bevel gear I3-4 to move, further the bevel gear I3-4 drives the bevel gear II 3-19 to move, the inner end sleeve I3-12 is driven to move by the bevel gear II 3-19, and the dust removal fan blades 3-18 are driven to move by the inner end sleeve I3-12, so that the dust removal fan blades 3-18 drive air to flow, and dust generated in the ore crushing process is discharged through the dust removal opening 3-7; meanwhile, the inner-end manual rotating rod 3-5 is manually rotated, the inner-end threaded sleeve 3-15 is driven to move through the inner-end manual rotating rod 3-5, the threaded sleeve hinge rod 3-16 is driven to move through the inner-end threaded sleeve 3-15, the hinged connecting rod 3-17 is driven to move through the threaded sleeve hinge rod 3-16, the dust removing fan blade 3-18 is driven to move through the hinged connecting rod 3-17, and the air flow rate of the dust removing fan blade 3-18 is changed.

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

1. The utility model provides a mineral secondary processing equipment, includes crushing unit (1), pan feeding subassembly (2), secondary treatment subassembly (3), driving belt three (4), driving belt one (5), driving belt two (6), its characterized in that: crushing unit (1) is connected with pan feeding subassembly (2), and pan feeding subassembly (2) is connected with secondary treatment subassembly (3), and driving belt three (4) are connected with secondary treatment subassembly (3), and driving belt one (5) are connected with pan feeding subassembly (2), secondary treatment subassembly (3), and driving belt two (6) are connected with crushing unit (1) and pan feeding subassembly (2).

2. A mineral secondary processing plant according to claim 1, characterized in that: the crushing assembly (1) comprises a crushing outer frame (1-1), a crankshaft (1-2), a driving rotating rod (1-3), a driving block (1-4), a driving block connecting rod I (1-5), a driving connecting rod I (1-6), a driving connecting rod II (1-7), a crushing sliding rod (1-8), a crankshaft limiting boss (1-9), a crushing vibration boss (1-10), an inner end spring I (1-11), an inner end spring II (1-12), a sealing ring (1-13), an inner end limiting frame (1-14), an inner end clamping groove I (1-15), an inner end clamping rod I (1-16) and an inner end clamping rod pushing spring I (1-17), wherein the crankshaft (1-2) is rotatably connected with the crushing outer frame (1-1), and the crankshaft limiting boss (1-9) is fixedly connected with the crankshaft (1-2), the driving rotating rod (1-3) is rotatably connected with the crushing outer frame (1-1), the driving block (1-4) is connected with the driving rotating rod (1-3) in a matching way, the inner end clamping groove I (1-15) is arranged on the driving rotating rod (1-3), the inner end clamping rod I (1-16) is connected with the driving block (1-4) in a sliding way, the inner end clamping rod push spring I (1-17) is arranged between the inner end clamping rod I (1-16) and the driving block (1-4), the inner end clamping rod I (1-16) is connected with the inner end clamping groove I (1-15) in a matching way, the driving block connecting rod I (1-5) is rotatably connected with the driving block (1-4), one end of the driving connecting rod I (1-6) is hinged with the driving block connecting rod I (1-5), the other end of the driving connecting rod I (1-6) is hinged with the driving connecting rod II (1-7), the other end of the driving connecting rod II (1-7) is hinged with a crushing slide rod (1-8), the crushing slide rod (1-8) is connected with a crushing vibration boss (1-10) in a sliding way, the crushing vibration boss (1-10) is connected with an inner end limiting frame (1-14) in a sliding way, the inner end limiting frame (1-14) is fixedly connected with a crushing outer frame (1-1), an inner end spring I (1-11) and an inner end spring II (1-12) are respectively arranged at two ends of the crushing slide rod (1-8), a sealing ring (1-13) is fixedly connected with the crushing vibration boss (1-10), the sealing ring (1-13) is connected with the crushing slide rod (1-8) in a sliding way, a crankshaft (1-2) is rotationally connected with the driving connecting rod I (1-6), and a plurality of crankshaft limiting bosses (1-9) are arranged, the first driving connecting rod (1-6) is arranged between two adjacent first driving connecting rods (1-6).

3. A mineral secondary processing plant according to claim 1, characterized in that: the feeding assembly (2) comprises a feeding outer frame (2-1), a feeding grid plate (2-2), grids (2-3), arc-shaped limiting chutes (2-4), driving bosses (2-5), driving slide bars (2-6), side wall chutes (2-7), inner end slide columns (2-8), inner end push springs (2-9), eccentric driving discs (2-10), driving belt wheels A (2-11), inner end slide bars (2-12), inner end clamping bars (2-13), inner end clamping bars push springs (2-14) and inner end clamping grooves (2-15), the feeding grid plate (2-2) is rotatably connected with the feeding outer frame (2-1), the grids (2-3) are arranged on the feeding grid plate (2-2), and a plurality of grids (2-3) are arranged on the grids (2-3), the arc-shaped limiting sliding chutes (2-4) are arranged on the feeding outer frame (2-1), the driving bosses (2-5) are connected with the arc-shaped limiting sliding chutes (2-4) in a sliding manner, the driving bosses (2-5) are fixedly connected with the feeding grid plate (2-2), the driving bosses (2-5) are connected with the driving sliding rods (2-6) in a sliding manner, the driving sliding rods (2-6) are connected with the side wall sliding chutes (2-7) in a sliding manner, the side wall sliding chutes (2-7) are arranged on the feeding outer frame (2-1), the inner end sliding columns (2-8) are arranged at the inner ends of the side wall sliding chutes (2-7), the driving sliding rods (2-6) are connected with the inner end sliding columns (2-8) in a sliding manner, two inner end push springs (2-9) are arranged, the two inner end push springs (2-9) are connected with the inner end sliding columns (2-8) in a sleeved manner, and a driving slide bar (2-6) is arranged between two inner end push springs (2-9), an eccentric driving disc (2-10) is rotatably connected with a feeding outer frame (2-1), a driving belt wheel A (2-11) is fixedly connected with the eccentric driving disc (2-10), an inner end slider I (2-12) is slidably connected with the driving slide bar (2-6), an inner end clamping bar II (2-13) is slidably connected with the inner end slider I (2-12), an inner end clamping bar II (2-13) is connected with an inner end clamping groove II (2-15) in a matching way, the inner end clamping groove II (2-15) is arranged on the eccentric driving disc (2-10), the inner end clamping bar push spring II (2-14) is arranged between the two inner end clamping bar II (2-13), the crushing outer frame (1-1) is fixedly connected with the feeding outer frame (2-1), and the transmission belt II (6) is connected between the crankshaft (1-2) and the driving belt wheel A (2-11).

4. A mineral secondary processing plant according to claim 1, characterized in that: the secondary treatment component (3) comprises a secondary treatment outer frame (3-1), a dust removal outer frame (3-2), a bevel gear rod I (3-3), a bevel gear I (3-4), an inner end manual rotating rod (3-5), an inner end carrier belt (3-6), a dust removal port (3-7), an inner end shaft I (3-8), an inner end shaft II (3-9), an inner end roller I (3-10), an inner end roller II (3-11), an inner end sleeve I (3-12), an inner end fixing boss (3-13), a discharge port (3-14), an inner end threaded sleeve (3-15), a threaded sleeve hinge rod (3-16), a hinge connecting rod (3-17), dust removal fan blades (3-18) and a bevel gear II (3-19), wherein the secondary treatment outer frame (3-1) is fixedly connected with the dust removal outer frame (3-2), a bevel gear rod I (3-3) is rotationally connected with a dedusting outer frame (3-2), a bevel gear I (3-4) is fixedly connected with the bevel gear rod I (3-3), the bevel gear I (3-4) is in meshing transmission with a bevel gear II (3-19), the bevel gear II (3-19) is fixedly connected with an inner end sleeve I (3-12), the inner end sleeve I (3-12) is rotationally connected with the dedusting outer frame (3-2), an inner end fixing boss (3-13) is fixedly connected with the inner end sleeve I (3-12), an inner end manual rotating rod (3-5) is rotationally connected with an inner end manual rotating rod (3-5), a discharge port (3-14) and a dedusting port (3-7) are both arranged on the secondary processing outer frame (3-1), and the discharge port (3-14) and the dedusting port (3-7) are respectively arranged on the same side of the secondary processing outer frame (3-1), an inner end threaded sleeve (3-15) is in threaded connection with an inner end manual rotating rod (3-5), the inner end threaded sleeve (3-15) is in hinged connection with a threaded sleeve hinge rod (3-16), the threaded sleeve hinge rod (3-16) is in hinged connection with a hinge connecting rod (3-17), the hinge connecting rod (3-17) is fixedly connected with a dust removal fan blade (3-18), the dust removal fan blade (3-18) is rotatably connected with an inner end sleeve I (3-12), an inner end shaft I (3-8) and an inner end shaft II (3-9) are both rotatably connected with a secondary treatment outer frame (3-1), the inner end shaft I (3-8) and the inner end shaft II (3-9) are respectively and fixedly connected with the inner end shaft I (3-8) and the inner end shaft II (3-9), an inner end carrying belt (3-6) is connected with the inner end shaft I (3-8), The inner end shaft II (3-9), the transmission belt III (4) is connected between the inner end shaft I (3-8) and the bevel gear rod I (3-3), the transmission belt I (5) is connected between the inner end shaft I (3-8) and the driving belt wheel A (2-11), and the secondary processing outer frame (3-1) is fixedly connected with the feeding outer frame (2-1).

5. A mineral secondary processing plant according to claim 2, characterized in that: the crankshaft (1-2) is provided with an input motor A.